JP7284382B2 - Construction data management system and its manufacturing method - Google Patents

Description

The present invention relates to a construction data management system and a manufacturing method thereof.

Information related to various types of construction is required to be properly managed and stored according to various regulations. For this reason, management systems have been proposed for managing information about construction.

For example, Patent Literature 1 discloses the following system for preventing falsification of construction data. In this system, time stamp data of construction data is generated by a time stamp bureau, which is a third-party organization independent of construction companies, construction machine manufacturers, workers, and the like. This timestamp data is generated by adding time information to the hash value of construction data and encrypting it with an encryption key. When verifying the construction data, the time-stamped construction data stored in the server is obtained, and the time-stamped data is decrypted to obtain a hash value. This hash value is compared with the hash value of the construction data included in the time-stamped construction data to determine if the construction data has been falsified. In this way, it is ensured that the construction data has not been tampered with.

For example, Patent Literature 2 discloses a construction management system in which various data acquired by a construction terminal during pile construction are transmitted from the construction terminal to a management server and deleted from the construction terminal. The reliability of the data is enhanced by not leaving the data to the contractor.

Although the technical field is different, for example, Patent Document 3 discloses a system for managing the manufacturing process of products. This process control system includes a distributed storage system in which computing devices functioning as a plurality of nodes are connected by a network in order to store the manufacturing process. The distributed storage system creates block data based on process information, and stores the block data in chronological order with past block data to increase the difficulty of falsification.

Also, the stored construction information is preferably correct and authenticated by an appropriate person. For example, Patent Literature 3 discloses that only data approved by an administrator is stored.

JP 2017-157879 A JP 2018-053468 A JP 2018-169798 A

An object of the present invention is to prevent falsification of stored construction data.

According to one aspect of the present invention, a construction data management system includes a management network in which a plurality of nodes are connected to each other to form a blockchain, and form data relating to first data relating to construction output from a site terminal. and a first terminal that performs approval processing on the form data received from the first terminal, transmits approval of the form data to the first terminal, and approves the form data. After sending the notification to the first terminal, the approved form data is sent to the management network. The approved form data is recorded in the blockchain when a consensus is formed among the plurality of nodes regarding the approved form data.

According to the present invention, falsification of saved construction data is prevented.

FIG. 1 is a block diagram showing an outline of a configuration example of a management system according to the first embodiment. FIG. 2 is a block diagram illustrating an outline of a configuration example of an information processing device included in the management system according to the embodiment; FIG. 3 is a diagram schematically showing an example of a data structure of a blockchain in which data according to the embodiment is stored; FIG. 4A is a diagram for explaining an outline of an example of construction data according to the embodiment; FIG. 4B is a diagram for explaining an outline of an example of construction data according to the embodiment; FIG. 5A is a sequence diagram outlining an example of data flow according to the first example of the embodiment. FIG. 5B is a sequence diagram outlining an example of data flow according to the second example of the embodiment. FIG. 5C is a sequence diagram outlining an example of data flow according to the third example of the embodiment. FIG. 5D is a sequence diagram outlining an example of data flow according to the fourth example of the embodiment. FIG. 5E is a sequence diagram outlining an example of data flow according to the fifth example of the embodiment. FIG. 5F is a sequence diagram schematically showing an example of data flow according to the sixth example of the embodiment. FIG. 5G is a sequence diagram outlining an example of data flow according to the seventh example of the embodiment. FIG. 5H is a sequence diagram outlining an example of data flow according to the eighth example of the embodiment. FIG. 6 is a diagram for explaining an example of a combination of various data according to the embodiment; FIG. 7 is a flowchart outlining an example of the operation of the site manager's PC according to the embodiment. FIG. 8A is a flowchart outlining an example of the operation of a node according to an embodiment; FIG. 8B is a flowchart outlining an example of the operation of a node according to an embodiment; FIG. 9A is a flowchart outlining an example of the operation of the confirmer PC according to the embodiment. FIG. 9B is a flowchart showing an overview of an example of the operation of the confirmer PC according to the embodiment; FIG. 10 is a sequence diagram for explaining an example of the flow of data saved by the management network. FIG. 11 is a block diagram showing an outline of a configuration example of a management system according to the second embodiment. FIG. 12A is a sequence diagram outlining an example of data flow according to the second embodiment. FIG. 12B is a sequence diagram outlining an example of data flow according to the second embodiment. FIG. 12C is a sequence diagram outlining an example of data flow according to the second embodiment.

[First Embodiment]
A first embodiment will be described with reference to the drawings. The management system according to the present embodiment is a system that stores and manages construction data including information on various constructions during construction and civil engineering work. In the management system, construction data is distributed and managed by multiple nodes connected in a peer-to-peer manner. In addition, construction data is saved in a format using blockchain. For these reasons, it is difficult for management systems to falsify construction data. The management system is provided with a mechanism for referring to the saved construction data and confirming that the data at hand of the user has not been tampered with.

<System configuration>
FIG. 1 shows an outline of a configuration example of a management system 1 according to this embodiment. As shown in FIG. 1 , the management system 1 includes a management network 110 , a site manager personal computer (PC) 120 , a site terminal 130 and a checker PC 140 . The management network 110 stores reliable construction data. The management network 110 is configured by connecting a plurality of servers or the like functioning as nodes to each other, for example, in a peer-to-peer network. The site terminal 130 is a terminal used at the construction site. The site terminal 130 collects construction-related data at the construction site. The on-site manager PC 120 sorts out the data acquired by the on-site terminal 130 and prepares a report based on the data. The site manager PC 120 broadcasts to the management network 110 data that needs to be recorded among data acquired by the site terminal 130 , processed data based on the data, report data, and the like. Each node of the management network 110 stores information based on data transmitted from the site manager PC 120 according to a predetermined method. Site manager PC 120 also transmits data to be reported to checker PC 140 . The confirmer PC 140 performs confirmation work related to construction based on the data acquired from the site manager PC 120 . Also, the confirmer PC 140 confirms the authenticity of the data acquired from the on-site manager PC 120 by collating with records stored in the management network 110 .

Management network 110 is a peer-to-peer network that includes multiple nodes. Five nodes, a first node 111, a second node 112, a third node 113, a fourth node 114, and a fifth node 115, are schematically shown in FIG. There may be any number of such nodes. A node may be, for example, a server device. Each node of the management network 110 stores construction data according to predetermined rules. Each node agrees to store the same data. That is, the management network 110 is a distributed ledger network. In this embodiment, construction data is recorded using blockchain technology. For example, each node gets the same construction data to record. Each node transmits block information including the construction data to be added to the blockchain to each other and confirms its identity. When each node determines that the block it is about to add to the blockchain matches the block that another node is about to add to the blockchain, each node adds that same block to the blockchain. to add. In this way, each node continues to hold the same blockchain. Note that the stored data may be encrypted as appropriate.

The site manager PC 120 is placed at, for example, a construction site and used by the site manager. The site manager PC 120 communicates with the site terminal 130 . The on-site manager PC 120 also connects to the Internet, for example, and communicates with the management network 110 and the confirmer PC 140 . The site manager PC 120 organizes data related to the construction performed at the construction site. Site manager PC 120 transmits construction data to be recorded to management network 110 . Each node of the management network 110 that receives the construction data stores the construction data in a predetermined manner. The management system 1 may be provided with a mechanism for automatically transmitting unprocessed data to be saved, such as data obtained by measurement, to the management network 110 so that the data is not processed by the site manager PC 120 or the like. Site manager PC 120 also transmits construction data to checker PC 140 .

The construction data transmitted from the site manager PC 120 to the management network 110 and the confirmer PC 140 includes data such as construction location, construction date and time, construction details, information on design, measurement data obtained by various measurements during construction, and construction status. It can be various data such as inspection results, report data created based on them, and the like.

The site terminal 130 is, for example, a tablet-type information terminal brought to the construction site. The site terminal 130 communicates with the site manager PC 120 . The site terminal 130 may be a device that collects construction site information, photographs the construction site, records various measurement data measured at the construction site, and inputs inspected construction conditions. Also, the site terminal 130 may be a device that is connected to a measuring device related to construction and acquires measurement data. In this case, field terminal 130 may be a dedicated computer for limited use. Also, the site terminal 130 may be a device that relays data between the measuring device and the site manager PC 120 . The site terminal 130 transmits the acquired various data to the site manager PC 120 . Although one site manager PC 120 and one site terminal 130 are illustrated in FIG. 1 , a plurality of site terminals 130 may be connected to one site manager PC 120 . Also, one on-site terminal 130 may be connected to a plurality of on-site manager PCs 120 .

The confirmer PC 140 is a PC used by a confirmer who confirms whether or not the construction data received from the site manager PC 120 is correct. The confirmer PC 140 may perform various processes on the construction data received from the site manager PC 120 . The confirmer PC 140 communicates with the management network 110 and the site manager PC 120 via the Internet, for example. Confirmer PC 140 receives data on construction from site manager PC 120 . The confirmer PC 140 requests the management network 110 for information related to construction data whose reliability is ensured, and acquires the information. Confirmer PC 140 compares the data obtained from site manager PC 120 with the data obtained from management network 110 to determine the authenticity of the data obtained from site manager PC 120 . The confirmer PC 140 performs management of construction status, inspection of construction results, and other various data processing based on the data acquired from the site manager PC 120 .

FIG. 1 shows one management network 110, one on-site manager PC 120, one on-site terminal 130, and one confirmer PC 140, but each of these may be any number. For example, when information on a plurality of construction sites and information on a plurality of construction stages are managed using one management network 110, there are a plurality of site manager PCs 120 and confirmer PCs 140 connected to one management network 110. When the same construction site is managed using different management networks 110 depending on the construction stage, one checker PC 140 may connect to a plurality of management networks 110 . In this case, different on-site manager PCs 120 are connected to each management network 110 .

<Configuration of information processing device>
A server, a PC, a tablet information terminal, a dedicated computer, and the like that constitute each of the devices described above generally have the configuration of an information processing device. FIG. 2 shows an outline of a configuration example of such an information processing apparatus 300. As shown in FIG. The information processing apparatus 300 includes a CPU (Central Processing Unit) 301, a RAM (Random Access Memory) 302, a ROM (Read Only Memory) 303, a storage 304, a communication device 305, and an input device, which are connected to each other via a bus line 308. 306, a display device 307, and the like.

The CPU 301 performs various signal processing and the like. A RAM 302 functions as a main storage device for the CPU 301 . The ROM 303 stores various programs and the like. A hard disk drive (HDD), a solid state drive (SSD), or the like is used for the storage 304, for example. Various information such as programs and parameters used by the CPU 301 are recorded in the storage 304 . Various data are recorded in the storage 304 . The information processing device 300 may include an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or the like.

The above-described program is provided via a communication line such as the Internet or various storage media, and installed in the information processing apparatus 300 . The information processing device 300 functions as a node of the management network 110, the site manager PC 120, the site terminal 130, the confirmer PC 140, or the like, depending on the installed program. That is, each program is provided to a plurality of information processing apparatuses, and the information processing apparatuses perform their respective functions, thereby forming the management system 1 .

A communication device 305 is used for communication with other devices. Communication device 305 may use various wired or wireless communication standards, for example. Various recording media such as semiconductor memory may be used for communication. Input device 306 may be, for example, a keyboard, mouse, touch panel, or the like. The display device 307 can be a liquid crystal display, an organic EL display, or the like.

<data structure>
In this embodiment, a blockchain is used as a database for recording construction data. FIG. 3 shows an outline of an example data structure of recorded data using blockchain. Blockchain 500, which includes a series of construction data, includes multiple blocks. For example, FIG. 3 shows the n−1 th block 510 , the n th block 520 and the n+1 th block 530 .

Each block contains a block header and construction data corresponding to a transaction list. The construction data is data to be recorded that is transmitted from the site manager PC 120 . The block header includes at least the hash value of the block header of the immediately preceding block, time information, and the Merkle root of construction data.

For example, some construction data 518 is recorded in the (n−1)th block 510 . At this time, the block header 511 of the n-1th block 510 contains the hash value 513 of the block header of the n-2th block. This block header 511 also includes time information 514 when the data is recorded. This block header 511 also contains Merkle root 515 , which is a hash value for construction data 518 .

Next, when the next construction data 528 is recorded in the n-th block 520, the block header 521 contains the hash value 523 of the block header 511 of the (n−1)-th block 510. FIG. Additionally, as with the n−1 th block 510 , the block header 521 includes time information 524 when recorded and a merkle root 525 of construction data 528 . Thus, the n-th block 520 in which the block header 521 and construction data 528 are paired is recorded.

Similarly, for the n+1th block 530, a block header 531 including a hash value 533 of the block header 521 of the nth block 520, time information 534, and a merkle root 535 of construction data 538 is created. Recorded with data 538 .

If the construction data 528 of the n-th block 520 is changed, the construction data 528 of the block 520 and the Merkle root 525 will not match. If the Merkle root 525 is changed in accordance with the construction data 528, the hash value 533 of the block header of the previous block recorded in the next n+1-th block 530 matches the hash value of the block header 521 of the n-th block 520. I will not. In this way, alteration of construction data stored in the blockchain 500 can be easily discovered. Based on this, the authenticity of the construction data stored in the blockchain 500 is guaranteed.

Here, each block includes the hash value of the block header of the immediately preceding block, but the present invention is not limited to this. Each block may contain, for example, a hash value of the entire previous block. In this way, each block may contain a value that is calculated based on data stored in the past and that changes when the data stored in the past changes.

<Example of construction data>
The management system 1 according to this embodiment can manage data of various constructions such as construction and civil engineering. The managed data may also include data relating to pile foundations. Taking the case of a pile foundation as an example, an example of the data structure when the measurement data during pile construction is used as construction data will be described with reference to FIGS. 4A and 4B.

As shown in FIG. 4A, measurement data may include, for example, the following information. A password can be set for each piece of measurement data. The measurement data may include a pile number identifying the pile, a pile code indicating a type of pile design, and the like. The measurement data may also include a construction ID and a construction name for identifying construction. The measurement data may include information such as position information indicating the position of the pile, construction date and time indicating the date and time when the construction was performed, and pile type indicating the type of pile. The measurement data may also include information such as rotational torque, current value, excavation depth, rotational speed, pile hole diameter, drilling fluid supply rate, etc., which may be measured by the pile driver during excavation. The information included in the measurement data may be part of the information described above, or may include other information.

FIG. 4A shows a case where one set of construction data is created by one measurement. However, it is not limited to this. As shown in FIG. 4B, a set of construction data may include data obtained from multiple measurements. In this case, as shown in FIG. 4B, data having the same pile code may be set as one set of construction data. A password for a set of construction data may be common. Also, the password may be different for each piece of measurement data included in one set of construction data. A set of measurement data having the same data other than pile codes may be set as one set of construction data, or various data may be set as one set of construction data.

Although FIG. 4A and FIG. 4B show an example of measurement data as construction data, the construction data is not limited to this. Construction data includes construction outline, measurement data, design data, construction status check result data, construction site photo data, construction report data, report data, report or document, etc. Alternatively, it may be data on which the confirmation stamp of the client or the like is affixed, or a combination thereof.

These data include, for example, information on N values such as depth and N value, information on auger heads such as minimum and maximum head diameters, excavation depth, excavation speed, auger head to be used, head diameter, pile diameter, pile circumference Fixing liquid supply amount, foot protection liquid supply amount, excavation information such as eccentricity, pile number, pile type, pile length, pile diameter, product name, manufacturing number, pile information such as joint, measured pile hole depth, auger Design values, planned values, measured values, check results, etc. for various information such as current value, maximum current value, integrated current value, information on bearing layer such as elapsed time, information on pile embedding such as pile erection position, pile head level, etc. There are various data.

Data recorded in one block chain 500 may be all data related to one construction. Moreover, construction data may be recorded in a plurality of blockchains 500 in a distributed manner, for example, depending on the type of construction. For example, construction data regarding pile foundations may be recorded in one blockchain 500 and construction data regarding structures may be recorded in another blockchain 500 .

Also, for example, construction data related to pile foundations may be distributed and recorded in a plurality of blockchains 500 . For example, data with the same stake code may be recorded on one blockchain 500 and data with different stake codes may be recorded on another blockchain 500 .

<Data flow>
Some examples of data flow in the management system 1 are described with reference to the sequence diagrams shown in FIGS. 5A-5H.

(first example)
A first example will be described with reference to the sequence diagram shown in FIG. 5A. The site terminal 130 transmits data on construction to the site manager PC 120 . The site manager PC 120 transmits the construction data based on the acquired data to the management network 110 together with the password so as to be recorded in the block chain 500 .

The management network 110 stores the construction data in the block chain 500 together with the password. At this time, the management network 110 calculates the Merkle root (hash value A) of the construction data using a hash function. The Merkle root (hash value A) of this construction data is also stored in the blockchain 500 . Information about the time when the construction data was recorded is also stored in the blockchain 500 . Management network 110 transmits the address of the added construction data to site manager PC 120 .

The site manager PC 120 also reports the same construction data as the data recorded in the block chain 500 to the confirmer PC 140 . At this time, the site manager PC 120 transmits the password corresponding to the construction data recorded in the block chain 500 together with the construction data and the address where the construction data acquired from the management network 110 is recorded to the confirmer PC 140. .

The confirmer PC 140 transmits the address and password obtained from the site manager PC 120 to the management network 110 and requests the hash value A of the construction data recorded in the block chain 500 . On the other hand, the management network 110 verifies the password, and if the combination of the address and the password is correct, transmits the hash value A corresponding to the address acquired from the confirmer PC 140 to the confirmer PC 140 .

The checker PC 140 uses the same hash function as the hash function used by the management network 110 to calculate the Merkle root (hash value B) of the construction data acquired from the site manager PC 120 . The confirmer PC 140 compares the hash value A acquired from the management network 110 and the hash value B based on the construction data acquired from the site manager PC 120, and confirms that they match. If these hash values match, it becomes clear that the construction data acquired from the site manager PC 120 has not been tampered with. In this way, the confirmer PC 140 can confirm the authenticity of the construction data.

(Second example)
A second example will be described with reference to the sequence diagram shown in FIG. 5B. Only points different from the first example will be described. In the first example, confirmer PC 140 requests hash value A from management network 110, and management network 110 transmits hash value A to confirmer PC 140 in response to this request. On the other hand, in the second example, when the construction data is recorded in the block chain 500, the hash value A is transmitted from the management network 110 to the confirmer PC 140. FIG.

Therefore, the site manager PC 120 sends the destination of the hash value A to the management network 110 together with the construction data when recording the construction data in the blockchain 500 . Based on this transmission destination, the management network 110 transmits the Merkle root (hash value A) of the recorded construction data to the confirmer PC 140 when the construction data is recorded in the block chain 500 . Therefore, site manager PC 120 does not need to send a password or address to checker PC 140, and may send only construction data. It should be noted that site manager PC 120 may specify a password, and confirmation person PC 140 may be configured to view hash value A by using this password.

As in the first example, the confirmer PC 140 compares the hash value A acquired from the management network 110 and the hash value B based on the construction data acquired from the site manager PC 120, and confirms that they match. to verify the authenticity of construction data.

(Third example)
A third example will be described with reference to the sequence diagram shown in FIG. 5C. Only points different from the first example will be described. In the first example, the checker PC 140 requests the hash value A from the management network 110, but in the third example, the checker PC 140 specifies an address to the management network 110 and requests construction data. Management network 110 transmits construction data specified by the address to confirmer PC 140 in response to a request from confirmer PC 140 .

As in the first example, the checker PC 140 calculates the hash value A, which is the Merkle root of the construction data A acquired from the site manager PC 120, and the Merkle root of the construction data B acquired from the management network 110. A hash value B is calculated. The confirmer PC 140 compares these two calculated hash values, confirms that they match, and confirms the authenticity of the construction data.

(Fourth example)
A fourth example will be described with reference to the sequence diagram shown in FIG. 5D. Only points different from the third example will be described. In a third example, confirmer PC 140 requests construction data B from management network 110, and management network 110 transmits construction data B to confirmer PC 140 in response to this request. On the other hand, in the fourth example, when the construction data is recorded in the block chain 500 , this construction data B is transmitted from the management network 110 to the confirmer PC 140 .

Therefore, when the construction data is recorded in the blockchain 500, the site manager PC 120 sends the construction data to the management network 110 together with the construction data destination. Based on this transmission destination, the management network 110 transmits the recorded construction data to the confirmer PC 140 when the construction data is recorded in the block chain 500 . Therefore, site manager PC 120 does not need to send a password or address to checker PC 140, and may send only construction data. Site manager PC 120 may designate a password so that confirmer PC 140 can view construction data B by using this password.

As in the third example, the checker PC 140 calculates the hash value A, which is the Merkle root of the construction data A acquired from the site manager PC 120, and the Merkle root of the construction data B acquired from the management network 110. A hash value B is calculated. The confirmer PC 140 compares these two calculated hash values, confirms that they match, and confirms the authenticity of the construction data.

(Fifth example)
A fifth example will be described with reference to the sequence diagram shown in FIG. 5E. Only points different from the third example will be described. In the third example, confirmer PC 140 compares hash value A of construction data A acquired from site manager PC 120 with hash value B of construction data B acquired from management network 110 . On the other hand, in the fifth example, the confirmer PC 140 compares the construction data A acquired from the site manager PC 120 and the construction data B acquired from the management network 110, and confirms that they match. Verify and verify the authenticity of construction data.

(Sixth example)
A sixth example will be described with reference to the sequence diagram shown in FIG. 5F. Only points different from the fifth example will be described. In the fifth example, the confirmation person PC 140 requested construction data B from the management network 110, but in the sixth example, when the construction data is recorded in the block chain 500, the management network 110 sends the confirmation person PC 140 This construction data B is transmitted.

Therefore, when the construction data is recorded in the blockchain 500, the site manager PC 120 sends the construction data to the management network 110 together with the construction data destination. Based on this transmission destination, the management network 110 transmits the recorded construction data to the confirmer PC 140 when the construction data is recorded in the block chain 500 . The confirmer PC 140 compares the construction data A acquired from the site manager PC 120 and the construction data B acquired from the management network 110, confirms that they match, and confirms the authenticity of the construction data. .

(Seventh example)
A seventh example will be described with reference to the sequence diagram shown in FIG. 5G. Only points different from the first example will be described. In a first example, the site manager PC 120 transmits construction data to the management network 110 and the construction data is recorded in the blockchain 500 . On the other hand, in the seventh example, the site manager PC 120 transmits the hash value of construction data to the management network 110, and the hash value is recorded in the block chain 500. FIG.

Therefore, the site manager PC 120 uses a hash function to calculate a hash value A, which is the Merkle root of the construction data. The site manager PC 120 transmits the hash value A together with the password to the management network 110 so as to be recorded in the block chain 500 . The management network 110 saves the hash value A together with the password in the blockchain 500 . The management network 110 transmits the address of the added hash value A to the on-site manager PC 120 .

The site manager PC 120 reports the construction data corresponding to the hash value recorded in the block chain 500 to the confirmer PC 140 . At this time, the site manager PC 120 transmits the password recorded in the block chain 500 and the address acquired from the management network 110 together with the construction data to the confirmer PC 140 .

Confirmer PC 140 transmits the address and password obtained from on-site manager PC 120 to management network 110 and requests hash value A recorded in block chain 500 . On the other hand, the management network 110 verifies the password, and when the correspondence between the address and the password is confirmed, the hash value A corresponding to the address acquired from the confirmer PC 140 is transmitted to the confirmer PC 140 .

The checker PC 140 uses the same hash function as the hash function used by the management network 110 to calculate the Merkle root (hash value B) of the construction data acquired from the site manager PC 120 . The confirmer PC 140 compares the hash value A acquired from the management network 110 and the hash value B based on the construction data acquired from the site manager PC 120, confirms that they match, and verifies the authenticity of the construction data. Check gender.

(Eighth example)
An eighth example will be described with reference to the sequence diagram shown in FIG. 5H. Only points different from the seventh example will be described. In the seventh example, the checker PC 140 requested the hash value A from the management network 110, but in the eighth example, when the hash value A is recorded in the block chain 500, the checker PC 140 is sent from the management network 110. Hash value A is sent to .

Therefore, the site manager PC 120 sends the destination of the hash value A together with the hash value A to the management network 110 when the construction data is recorded in the block chain 500 . Based on this transmission destination, the management network 110 transmits the recorded hash value A to the confirmation person PC 140 when the hash value A is recorded in the block chain 500 . As in the seventh example, the confirmer PC 140 compares the hash value A obtained from the management network 110 and the hash value B based on the construction data obtained from the site manager PC 120, and confirms that they match. to verify the authenticity of construction data.

(For other data in each example)
The above-described transmitted/received data is part of the data transmitted/received in the management system 1 . Other data is also sent and received in the management system 1 . For example, in order to transmit and receive data between the site manager PC 120 and the checker PC 140, mutual information and various arrangements regarding data to be transmitted and received are also transmitted and received.

For example, the on-site manager PC 120 may request the confirmation person's PC 140 to register for each work place, and the confirmation person's PC 140 may perform the work of registering the work place. Confirmer PC 140 may determine an ID for each work place and transmit the determined work place ID to site manager PC 120 . At this time, the workplace ID may be transmitted as a numerical value, or may be transmitted as an image such as a two-dimensional code. This workplace ID may be used as an ID or the like necessary for site manager PC 120 to access management network 110 . In addition, site manager PC 120 may add information about the corresponding workshop ID when transmitting data to confirmer PC 140 . This workplace ID may be used like a password. The data may be configured so that confirmer PC 140 can browse the data acquired from site manager PC 120 by inputting this workplace ID.

<Combination of data to be compared>
As described with reference to FIGS. 5A to 5H, the data transmitted from site manager PC 120 to checker PC 140 is necessary construction data. On the other hand, the data transmitted from the site manager PC 120 to the management network 110, the data recorded in the block chain 500 of the management network 110, the data transmitted from the management network 110 to the confirmer PC 140, and the authenticity of the data at the confirmer PC 140 The data and the like used for the determination may be various. For example, construction data, hash values thereof, etc., or various combinations thereof may be used. A list of examples is shown in FIG.

An example shown in (1) of FIG. 6 corresponding to the first example and the second example described above will be described. Construction data is transmitted from the site manager PC 120 to the management network 110 . This construction data is recorded in the block chain 500 of the management network 110 . In addition, the hash value of the construction data is also recorded in the block chain 500. The recorded hash value is transmitted from the management network 110 to the confirmer PC 140 . Confirmer PC 140 calculates the hash value of the construction data acquired from site manager PC 120 and compares it with the hash value acquired from management network 110 to confirm the authenticity of the construction data acquired from site manager PC 120 .

According to this method, agreed construction data is recorded in the management network 110 . Therefore, authentic construction data is stored in the management network 110 . Further, the data transmitted from the management network 110 to the confirmer PC 140 is a hash value, which is small in data volume and easy to handle. Moreover, since the comparison processing by the checker PC 140 is also performed between the hash values, the load of the comparison processing is small.

An example shown in (2) of FIG. 6 corresponding to the above-described third and fourth examples will be described. Construction data is transmitted from the site manager PC 120 to the management network 110 . This construction data is recorded in the block chain 500 of the management network 110 . The recorded construction data is transmitted from the management network 110 to the confirmer PC 140 . The checker PC 140 calculates the hash value of the construction data acquired from the site manager PC 120 and the hash value of the construction data acquired from the management network 110, compares the hash values, and obtains the hash value from the site manager PC 120. Check the authenticity of construction data.

According to this method, agreed construction data is recorded in the management network 110 . Therefore, authentic construction data is stored in the management network 110 . Further, since the comparison processing by the checker PC 140 is performed between hash values, the load of the comparison processing is small. Further, even if the construction data acquired from the site manager PC 120 is falsified, the confirmer PC 140 can acquire authentic construction data from the management network 110 .

An example shown in (3) of FIG. 6 corresponding to the fifth and sixth examples described above will be described. Construction data is transmitted from the site manager PC 120 to the management network 110 . This construction data is recorded in the block chain 500 of the management network 110 . The recorded construction data is transmitted from the management network 110 to the confirmer PC 140 . The confirmer PC 140 compares the construction data acquired from the site manager PC 120 and the construction data acquired from the management network 110 to confirm the authenticity of the construction data acquired from the site manager PC 120 .

According to this method, agreed construction data is recorded in the management network 110 . Therefore, authentic construction data is stored in the management network 110 . Further, even if the construction data acquired from the site manager PC 120 is falsified, the confirmer PC 140 can acquire authentic construction data from the management network 110 .

When the number of data is small, collation can be easily performed by such a method. When hash values are used for data comparison, not only data contents but also data formats are compared. Therefore, it is necessary to accurately unify data formats. On the other hand, when comparing construction data, the data can be compared even if the data formats are slightly different.

An example shown in (4) of FIG. 6 will be described. Construction data is transmitted from the site manager PC 120 to the management network 110 . A hash value of this construction data is recorded in the block chain 500 of the management network 110 . The recorded hash value is transmitted from the management network 110 to the confirmer PC 140 . Confirmer PC 140 calculates the hash value of the construction data acquired from site manager PC 120 and compares it with the hash value acquired from management network 110 to confirm the authenticity of the construction data acquired from site manager PC 120 .

According to this method, the data stored in the management network 110 are hash values, and the amount of stored data is small. Further, the data transmitted from the management network 110 to the confirmer PC 140 is a hash value, which is small in data volume and easy to handle. Moreover, since the comparison processing by the checker PC 140 is also performed between the hash values, the load of the comparison processing is small.

An example shown in (5) of FIG. 6 corresponding to the above-described seventh example and eighth example will be described. A hash value of construction data is transmitted from the site manager PC 120 to the management network 110 . A hash value of this construction data is recorded in the block chain 500 of the management network 110 . The recorded hash value is transmitted from the management network 110 to the confirmer PC 140 . Confirmer PC 140 calculates the hash value of the construction data acquired from site manager PC 120 and compares it with the hash value acquired from management network 110 to confirm the authenticity of the construction data acquired from site manager PC 120 .

According to this method, since the hash value of the construction data is transmitted to the management network 110, the nodes constituting the management network 110 do not touch the construction data. Therefore, the construction data is kept secret from the nodes forming the management network 110 . Also, the data stored in the management network 110 is a hash value, and the amount of stored data is small. Further, the data transmitted from the management network 110 to the confirmer PC 140 is a hash value, which is small in data volume and easy to handle. Moreover, since the comparison processing by the checker PC 140 is also performed between the hash values, the load of the comparison processing is small.

<System operation>
An outline of the operation of each part of the management system 1 will be described.

(Operation of site manager PC)
An outline of the operation of the site manager PC 120 when recording one piece of construction data in the management network 110 will be described with reference to the flowchart shown in FIG.

In step S101, the site manager PC 120 acquires construction data from the site terminal 130, for example.

In step S102, the site manager PC 120 creates storage data to be recorded in the block chain 500 based on the acquired construction-related data. For example, in the first to sixth examples described with reference to FIGS. 5A to 5F, the saved data is construction data. Also, for example, in the seventh and eighth examples described with reference to FIGS. 5G and 5H, the saved data is a hash value regarding construction data.

In step S<b>103 , site manager PC 120 broadcasts the saved data to management network 110 . The management network 110 records the data transmitted from the site manager PC 120 in the block chain 500 as construction data or the like. The management network 110 transmits to the site manager PC 120 address information specifying the construction data and the like transmitted from the site manager PC 120 and recorded in the block chain 500 .

In step S104, site manager PC 120 receives address information specifying the transmitted construction data from management network 110, and saves the received information.

In step S<b>105 , site manager PC 120 transmits to confirmer PC 140 the stored data, which is the construction data transmitted to management network 110 and stored in the management network, and the address information acquired from management network 110 . When the stored data is a hash value, the construction data that is the source of the stored data is transmitted instead of the stored data itself.

(node behavior)
An outline of the operation of the nodes included in the management network 110 will be described. Management network 110 includes a plurality of nodes. The processing described here is executed at each node.

First, the first, third, fifth and seventh examples described with reference to FIGS. 5A, 5C, 5E and 5G will be described with reference to the flowchart shown in FIG. 8A.

In step S<b>201 , the node determines whether or not saved data has been received from site manager PC 120 . When it is determined that the save data has been received, the process proceeds to step S202. In step S<b>202 , the node acquires saved data from site manager PC 120 .

If the acquired stored data is construction data as in the first to sixth examples described with reference to FIGS. Compute a certain hash value.

At step S<b>204 , the node creates a block to add to the blockchain 500 . A block includes a block header, construction data, and the like. Here, the block header includes the hash value of the block header of the previous block, time information, the Merkle root calculated in step S203, and the like.

In step S205, the node performs consensus processing. That is, multiple nodes form a consensus on a block to add to the blockchain 500 . For example, each node sends information about the blocks it has created to other nodes. Each node obtains information about blocks sent by other nodes and compares them with blocks it has created. If a block created by itself matches a block created by another node, the node sends information to the other node that the block is correct. When each node performs processing according to a determined procedure, the blocks created by each node match and are mutually confirmed. In such a case, an agreement is said to have been formed.

For example, in the case of the block chain 500 having the structure shown in FIG. 3, since the Merkle root of the construction data is included in the block header, if only the content of the block header is checked, the data of the block will match. can be confirmed. Also, a hash value of the block header may be recorded in the block header, and matching of the data of the block may be confirmed by comparing the hash value.

The management network 110 can also be configured so that a consensus can be formed even if the data created by all the nodes configuring the management network 110 do not match. For example, when the data created by more than a predetermined number of nodes match, the data is transmitted to each node constituting the management network 110 together with the fact that a consensus has been formed. All nodes record the data. Thus, the management network 110 may be configured.

At step S206, the node determines whether an agreement has been reached. When consensus is formed, the process proceeds to step S207.

In step S207, the node adds the created block data to the blockchain 500 and saves it.

In step S208, the node transmits address information specifying the added block to site manager PC 120 that transmitted the saved data. A series of processes for recording the received construction data is thus completed, and the process returns to step S201.

When it is determined in step S206 that no consensus has been formed, the process proceeds to step S209. In step S<b>209 , the node transmits error information to the on-site manager PC 120 to the effect that consensus could not be formed and the received stored data could not be recorded in the block chain 500 .

When it is determined in step S201 that the saved data has not been received, the process proceeds to step S210. In step S<b>210 , the node determines whether or not a data request has been received from confirmer PC 140 . For example, when confirmer PC 140 determines whether construction data acquired from site manager PC 120 is authentic, confirmer PC 140 transmits the address and password acquired from site manager PC 120 to management network 110 . Thus, when the address and password are received from the confirmer PC 140, the node determines that it has received the data request. When no data request has been received, the process returns to step S201. When a data request is received, the process proceeds to step S211.

In step S211, the node checks the address information included in the received data request against the password recorded at that address. When the passwords match, the node reads the requested data from blockchain 500 . In step S212, the node transmits the read requested data to the confirmer PC 140 that requested the data. After that, the process returns to step S201.

Next, the cases of the second, fourth, sixth and eighth examples described with reference to FIGS. 5B, 5D, 5F and 5H will be described with reference to the flow chart shown in FIG. 8B. Differences from the case shown in FIG. 8A will be described.

When it is determined in step S201 that the saved data has not been received, the process repeats step S201 and waits. When it is determined in step S201 that the saved data has been received, the process proceeds to step S202. Steps S202 to S208 are the same as those described above. Briefly, the node acquires stored data in step S202, calculates a hash value in step S203, and creates a block in step S204.

The node performs consensus processing in step S205, and when it is determined that a consensus has been formed in step S206, the processing adds and saves the block data to the blockchain 500 in step S207, and Send the address of the data you added to the . Thereafter, in step S220, the node transmits confirmation data to confirmer PC 140. FIG. The confirmation data may be a hash value, which is a Merkle root of the construction data, or the construction data itself. After that, the process returns to step S201. When it is determined in step S206 that no agreement has been formed, in step S209 an error is sent to the site manager PC 120, and the process returns to step S201.

(Operation of confirmer PC)
An outline of the operation of the confirmer PC 140 will be described. First, the cases of the first, third, fifth, and seventh examples described with reference to FIGS. 5A, 5C, 5E, and 5G, respectively, will be described with reference to the flowchart shown in FIG. 9A.

In step S<b>301 , confirmer PC 140 determines whether construction data and the like have been received from site manager PC 120 . When construction data is received, the process proceeds to step S302. In step S<b>302 , confirmer PC 140 acquires construction data, addresses, and the like from site manager PC 120 . In step S303, confirmer PC 140 records the acquired construction data, address, and the like. After that, the process returns to step S301.

When it is determined in step S301 that construction data has not been received, the process proceeds to step S304. In step S304, confirmer PC 140 determines whether or not to confirm data, that is, whether or not the user has input an instruction to confirm data. When it is determined not to confirm data, the process returns to step S301. On the other hand, when it is determined to confirm the data, the process proceeds to step S305.

In step S305, confirmer's PC 140 transmits the address of the data to be confirmed to management network 110 and requests the management network 110 for the data. This request may be sent to at least one of the nodes that make up the management network 110 . In response to this request, data is transmitted from the management network 110 to the confirmer PC 140 by the process of step S212 described above. In step S<b>306 , confirmer PC 140 receives the requested data from management network 110 . This data is, for example, a hash value of the construction data or the construction data itself.

In step S<b>307 , confirmer PC 140 calculates a hash value of construction data acquired from site manager PC 120 or management network 110 . In step S308, the confirmer PC 140 compares the construction data acquired from the site manager PC 120 or its hash value with the construction data acquired from the management network 110 or its hash value, and determines whether they match. In step S309, confirmer PC 140 outputs the result of the comparison. For example, when the values match, it can be determined that the construction data acquired from the site manager PC 120 is correct data recorded in the blockchain 500 .

Next, the cases of the second, fourth, sixth and eighth examples described with reference to FIGS. 5B, 5D, 5F and 5H will be described with reference to the flow chart shown in FIG. 9B. Differences from the case shown in FIG. 9A will be described.

In step S301, confirmer PC 140 determines whether construction data or the like has been received from site manager PC 120. When it is determined that construction data has been received, the process proceeds to step S302. Confirmer PC 140 acquires construction data and the like from site manager PC 120 in step S302, and records the acquired construction data and the like in step S303. After that, the process returns to step S301.

When it is determined in step S301 that construction data has not been received, in step S304, confirmer PC 140 determines whether or not to confirm the data. When it is determined not to confirm data, the process proceeds to step S310. In step S310, confirmer PC 140 determines whether confirmation data regarding the data added to block chain 500, transmitted from management network 110 in step S220, has been received. When it is determined that it has not been received, the process returns to step S301. On the other hand, when it is determined that it has been received, the process proceeds to step S311. Confirmer PC 140 acquires confirmation data from management network 110 in step S311, and records the acquired confirmation data in step S312. After that, the process returns to step S301.

When it is determined in step S304 that the data should be confirmed, the process proceeds to step S307. In step S<b>307 , confirmer PC 140 calculates a hash value of construction data acquired from site manager PC 120 or management network 110 . In step S308, the confirmer PC 140 compares the construction data acquired from the site manager PC 120 or its hash value with the construction data acquired from the management network 110 or its hash value, and determines whether they match. , output the result of the comparison.

<Node configuration>
A plurality of nodes that configure the management network 110 form a consensus when generating the block chain 500 . This agreement makes it difficult to falsify the construction data recorded in the blockchain 500. Therefore, in the present embodiment, node providers are selected to make falsification difficult. For example, if a construction company provides all the nodes, the construction company can freely rewrite the block chain 500, so such sharing of node provision is not appropriate. 4 illustrates some aspects of node provider combinations.

As a first example, one general contractor involved in one construction project and a plurality of contractors in different fields may each provide a node. For example, general contractors, piling contractors, bar arrangement contractors, structure contractors, exterior contractors, interior contractors, and the like each provide their own nodes. In this way, by not involving other companies in the same industry, mutual interests are not involved, and the objectivity of consensus building is further enhanced.

In addition, the general contractor will store the construction data in its own server by providing the node. Here, if all construction data relating to one construction work is stored in this management network 110, the general contractor stores all construction data relating to the construction work in its own server. As a result, for example, it becomes easier for the general contractor to hand over necessary data to the orderer.

As a second example, a single general contractor and multiple subcontractors in one area of the general contractor may each provide a node. For example, a general contractor and a plurality of piling contractors subcontracted by the general contractor each provide a node. In this way, by gathering contractors in one field, it is convenient for general contractors to collect construction data related to the field in one place. In addition, the general contractor will store the construction data in its own server by providing the node. As a result, for example, it becomes easier for the general contractor to hand over necessary data to the orderer. In this case, in order to prevent other companies in the same industry from sharing each other's raw construction data, for example, as shown in (5) of FIG. , may be a hash value of the construction data.

As a third example, multiple general contractors and multiple subcontractors in one area of the general contractor may each provide nodes. For example, a plurality of general contractors and a plurality of piling contractors subcontracted by the plurality of general contractors provide respective nodes. When multiple general contractors are contracted for one large-scale construction, construction data related to the relevant field is gathered in one place, which is convenient. In addition, the same thing as the second example can be said.

As a fourth example, when a plurality of general contractors undertake one large-scale construction work, a plurality of general contractors involved in the single construction work and a plurality of contractors in different fields may each provide nodes. It is convenient that many construction data of one large-scale construction are collected in one place. In addition, the same thing as the third example can be said.

As a fifth example, one subcontractor and a plurality of general contractors serving as prime contractors for the subcontractor may each provide a node. It is convenient that the construction data of the subcontractor is collected in one place.

<About the management system>
According to this embodiment, information related to construction data is stored in the blockchain 500 formed by agreement of multiple nodes provided by multiple companies that configure the management network 110 . The blockchain 500 with this consensus formed is distributed and stored in each node. Therefore, falsification of construction data is difficult, and falsification of construction data is prevented.

In addition, by using a blockchain and using the hash value of the block header to form consensus, the authenticity of past data is also confirmed when new construction data is recorded. Therefore, the authenticity of all construction data including past data can be easily maintained. By providing the nodes constituting the management network 110 by the confirmer, the confirmer can easily obtain construction data whose authenticity is guaranteed.

In addition, the confirmer PC 140 compares the construction data acquired from the site manager PC 120 or its hash value with the construction data acquired from the management network 110 or its hash value, thereby facilitating the presence or absence of falsification of the construction data. can be confirmed.

According to this embodiment, there is no need for an external certification authority or the like to intervene, so costs for the certification authority can be reduced. In addition, the data is stored in a server prepared by those involved in construction. Therefore, there is no need to prepare a third-party server or the like for storing data, and the cost for preparing a third-party server or the like can be reduced.

[Modification of First Embodiment]
<Regarding data recorded on the blockchain>
The above-described embodiment is an example in which data recorded in the block chain 500 is transmitted from the on-site manager PC 120 to the management network 110 . However, it is not limited to this. The data recorded in the block chain 500 may be data transmitted from the site terminal 130, data transmitted from the site manager PC 120, data transmitted from the confirmer PC 140, or a combination thereof.

An example of data recorded in the blockchain 500 will be described with reference to FIG. In FIG. 10, the on-site terminal is a measuring device that performs measurements related to construction, and the data output from the on-site terminal is measurement data. However, the present invention is not limited to this, and the on-site terminal may output various construction data as in the above-described embodiments. Part or all of the data shown in FIG. 10 or other data may be recorded in the blockchain.

The measurement data output from the field terminal may be recorded on the blockchain.
The measurement data output from the site terminal may be transmitted to the site manager PC, and the measurement data output by the site manager PC may be recorded in the blockchain.
The on-site manager PC may create a form using the measurement data acquired from the on-site terminal, and the created form may be recorded in the blockchain.
The form created by the on-site manager PC may be transmitted to the confirmer PC, and data of the form approved by the confirmer PC may be recorded in the blockchain.
The form created by the on-site manager PC may be transmitted to the confirmer PC, and the confirmer PC may transmit to the on-site manager PC an indication that the form is approved by the confirmer PC. In this case, the approved form data output from the confirmer's PC may be recorded in the blockchain. Also, the approved form data created by the on-site manager PC that received the approval from the confirmer PC may be output from the on-site manager PC, and the approved form data may be recorded in the blockchain.

<Regarding the structure of data recorded by the management network>
In the above-described embodiments, blockchain is used as a data structure for storing construction data. In this blockchain, blocks containing construction data are linked with each other through hash values. However, the data structure is not limited to blockchain. If the management networks 110 have the same data, it is difficult to tamper with all the data, and tampering is prevented. Therefore, data structures other than blockchain may be used as long as nodes can confirm that each other's data has not been tampered with.

<others>
In the above-described embodiment, the confirmer PC 140 acquires construction data from the site manager PC 120 and also receives authenticity-guaranteed data from the management network 110 . The confirmer PC 140 confirms the authenticity of the data acquired from the site manager PC 120 by comparing the data based on the data acquired from the site manager PC 120 and the data based on the data acquired from the manager PC 120. ing. However, it is not limited to this. If the data required by the checker PC 140 can be obtained from the management network 110, the checker PC 140 obtains the construction data as authenticity-guaranteed data from the management network 110, not from the site manager PC 120. You may

Further, in the above-described embodiment, an example has been described in which the consensus building in the management network 110 is based on the condition that the data match, but the present invention is not limited to this. For example, blockchain 500 and management network 110 may be configured such that each block contains a nonce and consensus is formed by proof of work by miners. In this case, miners are preferably provided with some kind of reward. The increased difficulty of adding blocks further increases the difficulty of tampering and increases the certainty that the stored data is genuine.

[Second embodiment]
A second embodiment will be described. Here, the points of difference from the first embodiment will be described, and the same reference numerals will be given to the same parts, and the description thereof will be omitted. FIG. 11 shows an outline of a configuration example of the management system 1 according to this embodiment. As shown in this figure, in this embodiment, the management system 1 has a construction management server 150 that relays various data related to construction and performs necessary processing on various data. In this embodiment, the construction management server 150 is connected to the management network 110 , and the site manager PC 120 and the confirmer PC 140 are connected to the construction management server 150 .

In this embodiment, the site manager PC 120 requests the confirmation person PC 140 to authenticate the construction data, and the confirmation person PC 140 can authenticate, correct, or send back the construction data in response to this authentication request. The data flow according to this embodiment will be described with reference to sequence diagrams shown in FIGS. 12A to 12C.

As shown in FIG. 12A, when the site terminal 130 acquires the measurement data, the measurement data is periodically transmitted to the site manager PC 120 . Site manager PC 120 transmits the received measurement data to construction management server 150 . The transmission of this measurement data is performed in real time, or periodically, such as every 3 minutes, 10 minutes, or 60 minutes. No modification of the measurement data is performed when transmitted in real time. For example, if the transmission interval is relatively long, such as every 60 minutes, the site manager's PC 120 can correct or edit the measurement data. When transmitting measurement data, an ID for specifying the data and a password for protecting the data may be added.

The construction management server 150 that has received the measurement data from the site manager PC 120 creates various documents such as forms and reports at regular intervals such as every 3 minutes, 10 minutes, and 60 minutes. The site manager PC 120 transmits the received measurement data and the created forms, reports, documents, etc. to the management network 110 in order to store them in the block chain 500 . As in the first embodiment, the management network 110 uses blockchain technology to store various data transmitted from the construction management server 150 in the blockchain 500 while obtaining consensus from multiple nodes.

As shown in FIG. 12B, on-site manager PC 120 transmits an ID and password for application software (app) running on checker PC 140 to checker PC 140 when data check by checker PC 140 is required. . Such an ID and password can control the access authority of the confirmer's PC 140 to the data output by the site manager's PC 120 .

Confirmer PC 140 starts the application and inputs the ID and password obtained from site manager PC 120 into the application. The application of confirmer PC 140 transmits the input ID and password to construction management server 150 . The construction management server 150 transmits data corresponding to the received ID and password, that is, data such as forms, reports, and documents associated with the ID and password acquired from the site manager PC 120 to the confirmer PC 140 . Confirmer PC 140 displays the received forms, reports, documents, and other data based on these documents. When a new form, document, or the like is created by the construction management server 150, the data is sent from the construction management server 150 to the confirmer's PC 140, and the confirmer's PC 140 updates the display.

As shown in FIG. 12C, measurement data is transmitted from the site terminal 130 to the site manager PC 120, and the site manager PC 120 transmits a signal requesting authentication by the confirmer PC 140 to the construction management server 150 together with the measurement data. do. For example, in the case of pile construction, this request for certification can be made at the completion of excavation, at the completion of the foot protection portion, at the completion of the pile circumference fixing portion, or the like.

For example, when excavation is completed, data measured during excavation such as an integrated current value, diagrams such as graphs representing them, display of an excavation completion mark, and an authentication request are transmitted. For example, when the foot protection part work is completed, the measurement data of the foot protection part such as the injection amount of concrete milk, the captured image of the measurement result display by the measuring device, the display of the foot protection part completion mark, and the authentication request are transmitted. be. For example, when the pile circumference fixing work is completed, the measurement data of the foot protection part such as the amount of concrete milk injected, the captured image of the measurement result display by the measuring device, the display of the pile circumference fixing part completion mark, and the certification request. sent.

The construction management server 150 transmits the forms, reports, documents, and the like created at the time of receiving the authentication request to the management network 110 so as to store them in the block chain 500 together with the authentication request information. The management network 110 that has obtained this information stores the information in the block chain 500 . In this way, data that may be modified is preserved, and the history is preserved even when modifications have been made.

In addition, the construction management server 150 transmits to the confirmer's PC 140 a notification that an authentication request has been made and information regarding the authentication request.

Upon receiving the authentication request, the confirmer PC 140 notifies the construction management server 150 of the fact when authenticating the information such as the measurement data. The authentication may be performed based on the integrated current value, etc., when excavation is completed, based on the captured image, etc., when the foot protection portion is completed, and based on the captured image, etc., when the pile circumference fixing portion is completed. .

The construction management server 150, which has received the information to authenticate from the confirmer PC 140, transfers the information to the management network 110 so that the information such as the authenticated measurement data, forms, documents, etc. is stored in the block chain 500 together with the authentication information. Send. The management network 110 that receives these information stores these information including authentication information in the block chain 500 .

Upon receiving the authentication request, the confirmer PC 140 denies and corrects the information such as the measurement data, corrects the data, and transmits the corrected data to the construction management server 150 . For example, if the authentication request information has a transcription error or the like, corrected data is created by correcting this. The construction management server 150 that has received this correction data transmits a correction notice to the effect that the correction has been received and a request to confirm the content of the correction to the site manager PC 120 .

Upon receiving the confirmation request, the site manager PC 120 sends the corrected measurement data and the like to the construction management server again together with the authentication request when there is no problem with the correction. After that, the corrected data is sent from the construction management server 150 to the management network 110 and stored in the block chain, and an authentication request notification and authentication request information are sent to the confirmer PC 140 in the same manner as the above process. If authentication by the confirmer PC 140 is performed, various data are stored in the block chain 500 together with the authentication information, and if not authenticated, corrections and the like are repeated again.

Upon receiving the confirmation request, the site manager PC 120 corrects the measurement data by himself when there is a problem with the correction, and transmits the corrected measurement data and the like to the construction management server again together with the authentication request. After that, the corrected data is sent from the construction management server 150 to the management network 110 and stored in the block chain, and an authentication request notification and authentication request information are sent to the confirmer PC 140 in the same manner as the above process. If authentication by the confirmer PC 140 is performed, various data are stored in the block chain 500 together with the authentication information, and if not authenticated, corrections and the like are repeated again.

When the confirmation person PC 140 receives the authentication request and returns the measurement data and the like to the site manager PC 120 , the confirmation person's PC 140 sends a message to that effect to the construction management server 150 . The construction management server 150 sends a return notice to the site manager PC 120 .

According to this embodiment, the data by the on-site manager PC 120 is confirmed by the confirmer PC 140 and stored in the block chain 500 together with the information indicating that it has been authenticated. Also, if there is a transcription error or the like, the mistake is corrected appropriately. For example, in the construction of piles, etc., manual transcription and input of inspection results are performed, and simple errors may occur in these tasks. Preferably, such errors are appropriately corrected and the corrected data saved. According to this embodiment, an appropriate correction is made and the corrected data is saved. Further, in this embodiment, information such as the history of correction is shared by all nodes. The monitoring function of each node prevents, for example, inappropriate changes to measured data that should not be corrected.

The confirmer PC 140 who can make corrections is, for example, the manager of a general contractor, and the design manager and client may not be able to make corrections, but only approve. Such authority differences can be managed by ID, for example.

The second embodiment can be combined with various items described as the first embodiment and its modifications.

The invention described in the scope of claims as originally filed in the original application will be additionally described below.
[1]
a management network in which multiple nodes are connected to each other;
a first terminal that transmits first data about construction data to each of the plurality of nodes;
a second terminal that performs confirmation processing regarding the construction data;
each of the plurality of nodes,
storing second data based on the first data when the plurality of nodes agree on the first data transmitted from the first terminal;
transmitting third data related to the second data to the second terminal;
Construction data management system.
[2]
According to [1], when saving new second data, the node saves, as the second data, data including a value calculated based on previously saved second data. management system.
[3]
The first terminal transmits the construction data to the second terminal,
The second terminal verifies the authenticity of the construction data by comparing data based on the construction data acquired from the first terminal and data based on the third data acquired from the management network. confirm,
The management system according to [1] or [2].
[4]
Multiple parties involved in one construction provide the node,
The node stores construction data related to the one construction,
The management system according to any one of [1] to [3].
[5]
The management system according to any one of [1] to [4], wherein one party provides the node for each construction field, and multiple parties in a plurality of construction fields provide the plurality of nodes.
[6]
The management system according to [4] or [5], wherein the first data includes at least part of the construction data.
[7]
The management system according to any one of [1] to [4], wherein a plurality of persons in the same construction field provide the nodes so that the plurality of persons provide the plurality of nodes.
[8]
The management system according to [7], wherein the first data is a hash value of the construction data.
[9]
Each of the nodes determines that a consensus is formed when it is determined that the second data stored in more than a predetermined number of nodes out of the plurality of nodes match, any one of [1] to [8]. or the management system according to item 1.
[10]
The third data according to any one of [1] to [9], wherein the third data is a hash value of data including at least part of the construction data, or includes at least part of the construction data. management system.
[11]
receiving the first data from the first terminal and transmitting data related to the first data to the node;
receiving the third data request from the second terminal and transmitting the third data request to the node;
any one of [1] to [9], further comprising a construction management server configured to receive the third data from the node and transmit the third data to the second terminal Management system as described in subsection.
[12]
The management system according to [11], wherein the construction management server creates a report or a form based on the first data, and transmits the report or the form to the node.
[13]
The construction data is data related to pile foundations, and includes data measured using a pile driver or data of construction inspection results, according to any one of [1] to [12]. management system.
[14]
providing a first program for causing a first terminal to transmit first data related to construction data to each of a plurality of nodes;
to said node,
causing the node to store second data based on the first data when a plurality of the nodes agree on the first data transmitted from the first terminal;
providing a second program for causing a second terminal to transmit third data included in the second data;
A method of manufacturing a construction data management system, comprising providing a third program for causing the second terminal to perform confirmation processing on the construction data using the third data.

DESCRIPTION OF SYMBOLS 1... Management system, 110... Management network, 111... First node, 112... Second node, 113... Third node, 114... Fourth node, 115... Fifth node, 120... Site manager PC 130 Field terminal 140 Checker PC 150 Construction management server 300 Information processing device 301 CPU 302 RAM 303 ROM 304 Storage 305 Communication device 306 Input device , 307... display device, 308... bus line, 500... block chain, 510, 520, 530... block, 511, 521, 531... block header, 513, 523, 533... hash value, 514, 524, 534... time information , 515, 525, 535 ... Merkle route, 518, 528, 538 ... construction data.

Claims (2)

a management network in which multiple nodes are connected to each other to form a blockchain;
a first terminal that creates form data related to first data related to construction output from a field terminal;
Approving the form data received from the first terminal, transmitting approval of the form data to the first terminal, and sending approval of the form data to the first terminal. a second terminal that transmits approved form data to the management network after transmitting to
When a consensus is formed between the plurality of nodes regarding the approved form data, the approved form data is recorded in the blockchain.
Construction data management system. a management network in which multiple nodes are connected to each other to form a blockchain;
a first terminal that creates form data related to first data related to construction output from a field terminal;
Approval processing is performed on the form data received from the first terminal, the approved form data is transmitted to the management network, and a notification to the effect that the form data has been approved is transmitted to the first terminal. 2 terminals;
A construction data management system comprising
The first terminal is
when receiving approval of the form data from the second terminal, transmitting the form data as approved form data to a management network;
When a consensus is formed between the plurality of nodes regarding the approved form data, the approved form data is recorded in the blockchain.
Construction data management system.

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