JP2021086447A - Data generation system, data generation method, and program - Google Patents

Abstract

To provide a data generation system capable of reducing workload related to facility maintenance, a data generation method, and a program.SOLUTION: A data generation system 1 includes a first acquisition unit 11, a second acquisition unit 12, and a generation unit 13. The first acquisition unit 11 acquires space information D1 relevant to the configuration of an object space of a facility. The second acquisition unit 12 acquires facility information D2 relevant to equipment placed in the object space. The generation unit 13 associates the space information D1 with the facility information D2 to generate facility data.SELECTED DRAWING: Figure 1

Description

The present disclosure relates generally to data generation systems, data generation methods and programs, and more specifically to data generation systems, data generation methods and programs that generate data related to the facility.

Patent Document 1 describes a remodeling sales support device that promotes remodeling sales. This remodeling sales support device receives a selection command from the user for selecting one of the floor plan information from a plurality of types of floor plan information stored in the floor plan information storage means, and the selected floor plan information and the selected floor plan information. Create a floor plan image based on the skeleton information. Therefore, the user can specifically recognize the state of the remodeled dwelling unit by looking at the floor plan image, and the purchase motivation is aroused.

JP-A-2007-293633

However, since the technology described in Patent Document 1 cannot reflect detailed information on the facility to be remodeled, for example, what kind of equipment is installed in the facility during maintenance (including remodeling) of the facility. It is necessary to actually check the site (facility), such as whether or not it is.

The present disclosure has been made in view of the above reasons, and an object of the present disclosure is to provide a data generation system, a data generation method, and a program capable of reducing the work load related to the maintenance of the facility.

The data generation system according to one aspect of the present disclosure includes a first acquisition unit, a second acquisition unit, and a generation unit. The first acquisition unit acquires spatial information regarding the shape of the target space of the facility. The second acquisition unit acquires equipment information regarding equipment installed in the target space. The generation unit generates facility data by associating the spatial information with the equipment information.

The data generation method according to one aspect of the present disclosure includes a first acquisition process, a second acquisition process, and a generation process. The first acquisition process is a process for acquiring spatial information regarding the shape of the target space of the facility. The second acquisition process is a process for acquiring equipment information regarding the equipment installed in the target space. The generation process is a process of generating facility data by associating the spatial information with the equipment information.

The program according to one aspect of the present disclosure is a program for causing one or more processors to execute the data generation method.

According to the present disclosure, there is an advantage that the work load related to the maintenance of the facility can be reduced.

FIG. 1 is a system configuration diagram showing a schematic configuration of a data generation system according to the first embodiment. FIG. 2 is an explanatory diagram conceptually showing the state of spatial information generation in the shape measurement system used together with the above-mentioned data generation system. FIG. 3 is an explanatory diagram conceptually showing how equipment information is generated in the sensor system used together with the data generation system described above. FIG. 4 is a flowchart showing an example of the data generation method according to the first embodiment. 5A and 5B are explanatory views conceptually showing the processing of facility data generation by the same data generation system. 6A and 6B are explanatory views showing an example of a display screen when the facility data generated by the same data generation system is displayed on the information terminal. FIG. 7 is a system configuration diagram showing a schematic configuration of the data generation system according to the second embodiment.

(Embodiment 1)
(1) Outline An outline of the data generation system 1 according to the present embodiment will be described with reference to FIGS. 1 to 3.

The data generation system 1 is a system for generating data related to the facility F1 (see FIG. 2). In the present embodiment, as an example, the facility data D10 (see FIG. 3) generated by the data generation system 1 is used for the maintenance of the facility F1, particularly the maintenance of the equipment 9 (see FIG. 2) installed in the facility F1. Be done. That is, the facility data D10 generated by the data generation system 1 includes information about the facility 9 installed in the facility F1 in addition to the information about the facility F1 itself such as the layout of the facility F1. Therefore, the facility data D10 can be used not only for the maintenance of the facility F1 itself, but also for the maintenance of the equipment 9 installed in the facility F1.

The data generation system 1 according to the present embodiment adopts the following configuration in order to generate such facility data D10. That is, as shown in FIG. 1, the data generation system 1 includes a first acquisition unit 11, a second acquisition unit 12, and a generation unit 13. The first acquisition unit 11 acquires spatial information D1 regarding the shape of the target space A1 of the facility F1. The second acquisition unit 12 acquires the equipment information D2 regarding the equipment 9 installed in the target space A1. The generation unit 13 generates the facility data D10 by associating the spatial information D1 with the equipment information D2.

According to this configuration, the facility data D10 is generated by associating the spatial information D1 with the equipment information D2. In other words, the facility data D10 is data obtained by associating the spatial information D1 with the equipment information D2. The spatial information D1 is information about the shape of the target space A1 of the facility F1, and the equipment information D2 is information about the equipment 9 installed in the target space A1. Therefore, in the facility data D10, the information regarding the shape of the target space A1 of the facility F1 (spatial information D1) and the information regarding the equipment 9 installed in the target space A1 (of the facility F1) (equipment information D2) are linked. It is attached. Such facility data D10 can be used not only for the maintenance of the facility F1 itself, but also for the maintenance of the equipment 9 installed in the facility F1. Therefore, for example, when the facility data D10 is used in the maintenance of the facility F1, it takes time and effort to actually confirm the site (facility F1) such as what kind of equipment 9 is installed in the facility F1. It will be reduced. As a result, it is possible to reduce the work load related to the maintenance of the facility F1.

(2) Details Hereinafter, the configuration of the data generation system 1 according to the present embodiment will be described in detail with reference to FIGS. 1 to 3.

(2.1) Definition The term "facility" as used in this disclosure means non-residential facilities such as offices, factories, buildings, stores, schools, welfare facilities or hospitals, as well as detached houses, apartments, or apartments. Includes residential facilities. Non-residential facilities include theaters, movie theaters, public halls, amusement parks, complex facilities, restaurants, department stores, hotels, inns, kindergartens, libraries, museums, art galleries, underground streets, stations and airports. Furthermore, the "facility" referred to in the present disclosure includes not only buildings (buildings) but also outdoor facilities such as stadiums, gardens, parking lots, grounds and parks. In the present embodiment, as an example, the facility F1 in which the facility data D10 is generated by the data generation system 1 will be described as an apartment house.

The "target space" referred to in the present disclosure is a space set in the facility F1. Here, the target space A1 is a space whose shape is represented by the space information D1. In the present embodiment, as an example, the internal space of the facility F1 composed of an apartment house, more specifically, the internal space of each room of each dwelling unit constitutes the target space A1.

"Equipment" as used in the present disclosure includes various equipment installed and used in facility F1, and includes equipment, devices and systems. As an example of equipment 9, air conditioning equipment 91 (see FIG. 2), lighting equipment 92 (see FIG. 2), wash basin, ventilation fan, system kitchen, IH heater, dishwasher, toilet, unit bath, distribution board, wiring equipment , Security equipment, disaster prevention equipment, interphones, refrigerators, TV receivers, etc. Further, the equipment 9 includes outdoor equipment such as a hot water supply equipment, an outdoor unit of an air conditioning equipment, a solar power generation equipment, a power conditioner, and a charging equipment for an electric vehicle. In the present embodiment, as an example, a case where the equipment 9 is installed in a fixed position of the facility F1 such as the air conditioning equipment 91 and the lighting equipment 92 will be described. When the air conditioner 91 and the lighting equipment 92 are not particularly distinguished, each of the air conditioner 91 and the lighting equipment 92 is also referred to as “equipment 9”.

"Maintenance" as used in the present disclosure means inspection, maintenance, repair, repair, etc. of facility F1 (including equipment 9) for the purpose of maintaining the normal condition of facility F1 (including equipment 9 installed in facility F1). Means to do. Maintenance includes "remodeling" of facility F1. The "reform" referred to in the present disclosure includes not only repair of facility F1 (including equipment 9) deteriorated due to aging deterioration, but also addition of new equipment 9 to facility F1, replacement of equipment 9, and usability. Includes renovation to improve.

The term "correspondence" as used in the present disclosure means that two or more objects are in a state of being in a corresponding relationship, that is, in a state of being in a relative relationship. Therefore, in the data generation system 1, the facility data D10 is generated by associating the spatial information D1 acquired by the first acquisition unit 11 and the equipment information D2 acquired by the second acquisition unit 12 with each other.

The "spatial information" referred to in the present disclosure is information regarding the shape of the target space A1 of the facility F1, and is, for example, information indicating the floor plan or size (width) of the target space A1. In the present embodiment, since the target space A1 is the internal space (indoor space) of the facility F1 (here, the housing complex), the space information D1 includes information regarding the floor plan of the facility F1.

Further, the "shape" of the target space A1 represented by the "spatial information" may be a two-dimensional shape or a three-dimensional shape. That is, the spatial information D1 may be information about a two-dimensional shape which is the shape of the target space A1 in a plan view as represented by a two-dimensional floor plan, or the two-dimensional shape in the height direction. It may be information about a three-dimensional shape to which a component is added. In this embodiment, as an example, it is assumed that the "shape" of the target space A1 represented by "spatial information" is a three-dimensional shape.

(2.2) Data Generation System First, the configuration of the data generation system 1 according to the present embodiment will be described.

As described above, the data generation system 1 includes a first acquisition unit 11, a second acquisition unit 12, and a generation unit 13. Further, in the present embodiment, in addition to the first acquisition unit 11, the second acquisition unit 12, and the generation unit 13, the data generation system 1 updates the display output unit 14, the data output unit 15, and the data output unit 15, as shown in FIG. A unit 16 and a storage unit 17 are further provided.

In this embodiment, as an example, all the components of the data generation system 1 are integrated into one housing. That is, in the data generation system 1, the first acquisition unit 11, the second acquisition unit 12, the generation unit 13, the display output unit 14, the data output unit 15, the update unit 16, and the storage unit 17 are all housed in one housing. Has been done.

Further, in the present embodiment, the data generation system 1 mainly includes a computer system including one or more memories and one or more processors. In other words, the function of the data generation system 1 is realized by the processor executing the program recorded in the memory of the computer system. In particular, among the data generation system 1, the computer system is the main configuration for the functions of the first acquisition unit 11, the second acquisition unit 12, the generation unit 13, the display output unit 14, the data output unit 15, and the update unit 16. Become. The program may be pre-recorded in a memory, provided through a telecommunication line such as the Internet, or may be recorded and provided on a non-temporary recording medium such as a memory card.

Further, the data generation system 1 according to the present embodiment acquires spatial information D1 and equipment information D2 from the shape measurement system 2 and the sensor system 3, respectively, by communication. Therefore, the data generation system 1 is configured to be able to communicate with each of the shape measurement system 2 and the sensor system 3. The term "communicable" as used in the present disclosure means that signals can be exchanged directly or indirectly via a network 6 or a repeater by an appropriate communication method of wired communication or wireless communication.

Further, in the present embodiment, the facility data D10 generated by the data generation system 1 is used, for example, for display on the information terminal 4 or predetermined processing on the data processing system 5. Therefore, the data generation system 1 is configured to be able to communicate with each of the information terminal 4 and the data processing system 5. The information terminal 4 is, for example, an information terminal having a communication function such as a smartphone or a tablet terminal, and is configured to be capable of displaying at least facility data D10. The data processing system 5 is, for example, an information processing system having a communication function such as a server or a cloud (cloud computing), and executes a predetermined process using the facility data D10. The "predetermined process" referred to in the present disclosure includes various processes using the facility data D10, for example, a simulation of the operation of the equipment 9, creation of a database including the facility data D10, or a machine that inputs the facility data D10. Includes processing such as learning.

In this embodiment, as an example, the data generation system 1, the shape measurement system 2, the sensor system 3, the information terminal 4, and the data processing system 5 are all connected to a network 6 such as the Internet. As a result, the data generation system 1 can exchange signals with the shape measurement system 2 and the sensor system 3 and the like via the network 6 by communication.

As described above, the first acquisition unit 11 acquires the spatial information D1. The spatial information D1 is information regarding the shape of the target space A1 of the facility F1. In particular, in the present embodiment, as described above, the spatial information D1 is information regarding the three-dimensional shape of the target space A1. Here, the first acquisition unit 11 acquires the spatial information D1 from the shape measurement system 2 by communication. Details will be described in the column of "(2.3) Shape measurement system", but as shown in FIG. 2, the shape measurement system 2 is based on the measurement data measured at the facility F1 using the measurement terminal 21. Spatial information D1 is generated. In other words, the spatial information D1 acquired by the first acquisition unit 11 from the shape measurement system 2 is information generated based on the measurement data measured by the facility F1.

The second acquisition unit 12 acquires the equipment information D2 as described above. The equipment information D2 is information about the equipment 9 installed in the target space A1. Here, the second acquisition unit 12 acquires the equipment information D2 from the sensor system 3 by communication. Details will be described in the column of "(2.4) Sensor system", but as shown in FIG. 3, the sensor system 3 is based on sensor data such as a physical quantity acquired from the target space A1 using the sensor terminal 31. Then, the equipment information D2 is generated. In other words, the equipment information D2 acquired by the second acquisition unit 12 from the sensor system 3 includes environmental information based on the sensor data acquired from the target space A1 in which the equipment 9 is installed.

The generation unit 13 generates the facility data D10 as described above. Here, the generation unit 13 generates the facility data D10 by associating at least the spatial information D1 with the equipment information D2. Details will be described in the column of "(3) Data generation method", but in the present embodiment, as an example, the generation unit 13 links the spatial information D1 and the equipment information D2 to the spatial information D1 and the equipment information D2. Generate facility data D10 including the combination with. In other words, the facility data D10 generated by the generation unit 13 is data that includes a combination of the spatial information D1 and the equipment information D2 and that defines the correspondence between the spatial information D1 and the equipment information D2.

Further, in the present embodiment, the generation unit 13 generates facility data D10 for each target space A1. That is, if a plurality of target spaces A1 are set in the facility F1, the generation unit 13 generates a plurality of facility data D10 for the plurality of target spaces A1.

The display output unit 14 outputs display data for displaying the facility data D10. In the present embodiment, as an example, the display output unit 14 outputs (transmits) display data to the information terminal 4 via the network 6 to display the facility data D10 on the information terminal 4. The display output unit 14 operates on a graphical user interface (GUI) of a computer system. That is, the display output unit 14 can display the screen including the facility data D10 on the information terminal 4 whose main configuration is the computer system. More specifically, the information terminal 4 is equipped with a Web browser function, and displays an image (screen) transmitted (distributed) from the display output unit 14 of the data generation system 1 on the display unit 41 (see FIG. 6A). indicate. The display mode of the facility data D10 on the information terminal 4 will be described in detail in the column of "(4) Example of utilization of facility data".

The data output unit 15 outputs the facility data D10 to the data processing system 5. As described above, the data processing system 5 executes a predetermined process (simulation, database creation, machine learning, etc.) using the facility data D10. In the present embodiment, as an example, the data output unit 15 causes the data processing system 5 to execute a predetermined process by outputting (transmitting) the facility data D10 to the data processing system 5 via the network 6.

The update unit 16 updates the facility data D10. That is, in the present embodiment, the facility data D10 generated by the generation unit 13 is not fixed (immutable) but can be updated (changed) by the updating unit 16.

The storage unit 17 stores the spatial information D1 acquired by the first acquisition unit 11, the equipment information D2 acquired by the second acquisition unit 12, the facility data D10 generated by the generation unit 13, and the like. Further, the storage unit 17 further stores information and the like necessary for the calculation in the generation unit 13 and the like. The storage unit 17 includes a rewritable non-volatile memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory).

Further, the data generation system 1 may further include a communication unit, a user interface, and the like in addition to the above configuration. However, the communication unit, the user interface, and the like are not essential configurations for the data generation system 1. In FIG. 1, as a configuration of the data generation system 1, a configuration other than the first acquisition unit 11, the second acquisition unit 12, the generation unit 13, the display output unit 14, the data output unit 15, the update unit 16, and the storage unit 17 is shown. Is omitted as appropriate.

The communication unit is configured to communicate directly with an external system (including the shape measurement system 2, the sensor system 3, the information terminal 4, and the data processing system 5) directly or indirectly via a network or a repeater. ing. As a result, the data generation system 1 can exchange data such as facility data D10 with the external system.

The user interface includes, for example, a touch panel display, accepts operations by a person (worker, etc.), and presents (displays) information to the person. The user interface is not limited to the touch panel display, and may have an input device such as a keyboard, a pointing device, a mechanical switch, or a gesture sensor. Further, the user interface may have an audio input / output unit instead of the touch panel display or together with the touch panel display.

(2.3) Shape Measurement System Next, the shape measurement system 2 used together with the data generation system 1 according to the present embodiment will be described with reference to FIGS. 1 and 2.

As shown in FIG. 1, the shape measuring system 2 includes a measuring terminal 21. As shown in FIG. 2, the measuring terminal 21 has a size that can be carried by the worker H1 and is realized by, for example, a tablet terminal or the like. The measuring terminal 21 includes measuring means (sensors) such as an image sensor (camera), a distance image sensor, a sonar sensor, a radar, or LiDAR (Light Detection and Ranging). To measure. Specifically, the measuring terminal 21 measures the distance to a structure such as a wall, a floor, a pillar, or a ceiling existing in a range that can be seen from the measuring terminal 21 and the shape of the structure by the measuring means.

According to such a shape measurement system 2, it is possible to generate spatial information D1 regarding the shape of the target space A1 of the facility F1. For example, as shown in FIG. 2, the worker H1 stands in the target space A1 of the facility F1 while holding the measurement terminal 21, moves in the target space A1, or directs the measurement terminal 21 in various directions. By doing so, the three-dimensional shape of the target space A1 can be measured by the measuring means. The plurality of measurement data obtained by the measurement terminal 21 are combined in the measurement terminal 21 and processed into spatial information D1 representing the three-dimensional shape of the target space A1.

That is, according to the shape measurement system 2, the spatial information D1 as shown in FIG. 2 is generated based on the measurement data measured at the facility F1. The spatial information D1 generated by the shape measurement system 2 in this way is transmitted from the shape measurement system 2 to the data generation system 1 (first acquisition unit 11) at any time.

Further, in FIG. 2 and the like, the spatial information D1 is given a reference code for the facility F1 and the target space A1, which indicates that the spatial information D1 corresponds to the facility F1 and the target space A1. In fact, the spatial information D1 does not include the facility F1 and the target space A1.

By the way, the measurement of the measurement data by the shape measurement system 2 is performed at the timing when the worker H1 enters the target space A1, such as a preview inspection (finishing inspection) performed when the facility F1 is completed, as an example. As a result, when the worker H1 performs work such as a preview inspection, measurement data for generating the spatial information D1 can be collected, and an increase in the burden on the worker H1 can be suppressed.

When measuring measurement data at such timing, as shown in FIG. 2, for example, equipment 9 such as air conditioning equipment 91 or lighting equipment 92 is already installed on a wall or ceiling at the time of measurement. Sometimes. Therefore, although the equipment 9 (air conditioning equipment 91 or lighting equipment 92, etc.) is not shown in the spatial information D1 in FIG. 2, the shape of the equipment 9 (air conditioning equipment 91, lighting equipment 92, etc.) is also spatial information. It will be reflected in D1. Further, similarly, the fittings such as doors and windows are not shown in the spatial information D1 in FIG. 2, but in reality, the shape of the fittings is also reflected in the spatial information D1.

(2.4) Sensor System Next, the sensor system 3 used together with the data generation system 1 according to the present embodiment will be described with reference to FIGS. 1 and 3.

As shown in FIG. 1, the sensor system 3 includes a plurality of sensor terminals 31. As shown in FIG. 3, the sensor terminal 31 has a shape and size that can be installed on the wall or ceiling of the facility F1. The sensor terminal 31 includes a temperature sensor, a humidity sensor, a pressure (pressure) sensor, a light (brightness) sensor, an acceleration sensor, an air flow (wind speed) sensor, an image sensor (camera), a sound sensor, an odor sensor, and a current / voltage sensor. Includes multiple types of sensors such as air quality sensors or vibration sensor. Each sensor terminal 31 has one or more of these plurality of types of sensors. Each sensor terminal 31 detects a desired physical quantity by converting the physical quantity into an electric signal with various sensors as described above. By using a plurality of types of sensors, it is possible to detect various physical quantities such as temperature, humidity, atmospheric pressure, illuminance, air flow, sound, vibration, and air quality.

According to such a sensor system 3, it is possible to generate equipment information D2 regarding the equipment 9 installed in the target space A1. For example, as shown in FIG. 3, the specifications of the equipment 9 are specified by installing a plurality of sensor terminals 31 at appropriate locations in the target space A1 in which the equipment 9 is installed and operating (operating) the equipment 9 in this state. , Performance, function, etc. can be detected. Here, it is preferable that the plurality of sensor terminals 31 include the above-mentioned plurality of types of sensors so that at least the plurality of sensor terminals 31 as a whole can detect a plurality of types of physical quantities (temperature, humidity, illuminance, etc.). Sensor data corresponding to various physical quantities detected by the plurality of sensor terminals 31 is collected by the sensor terminal 31 as one of the master units and processed into environmental information. The environmental information includes information on the distribution of physical characteristics such as temperature, humidity, pressure (atmospheric pressure), illuminance or air flow in the target space A1. The sensor terminal 31 as a master unit generates equipment information D2 including the above-mentioned environmental information based on the sensor data detected by the plurality of sensor terminals 31.

That is, according to the sensor system 3, the equipment information D2 including the environmental information based on the sensor data acquired from the target space A1 in which the equipment 9 is installed is generated. However, the sensor data is not limited to being directly acquired from the target space A1, and may be indirectly acquired from the target space A1. For example, even if the sensor terminal 31 is installed in a room next to the target space A1, under the floor, or behind the ceiling, physical quantities such as sound or vibration can be indirectly acquired as sensor data from the target space A1.

Here, the environmental information includes information on the distribution of physical characteristics (temperature, humidity, atmospheric pressure, illuminance, air flow, etc.) in the target space A1. In other words, the sensor system 3 generates equipment information D2 including environmental information regarding the distribution of physical characteristics in the target space A1. In the present embodiment, as described above, the equipment 9 that is the target of the equipment information D2 is installed in a fixed position of the facility F1. Therefore, for example, for the air-conditioning equipment 91, the sensor system 3 can generate the equipment information D2 including the temperature distribution and the airflow distribution in the target space A1 when the air-conditioning equipment 91 is in operation as environmental information. .. Further, for example, for the lighting equipment 92, the sensor system 3 can generate equipment information D2 including the distribution of illuminance in the target space A1 when the lighting equipment 92 is in operation (lighting) as environmental information. The equipment information D2 generated by the sensor system 3 in this way is transmitted from the sensor system 3 to the data generation system 1 (second acquisition unit 12) at any time.

Further, the equipment information D2 transmitted to the data generation system 1 is combined with the spatial information D1 to generate the facility data D10 including the spatial information D1 and the equipment information D2 in the data generation system 1. Therefore, in FIG. 3, the equipment 9 (air conditioning equipment 91 and lighting equipment 92) in the facility data D10 is designated by the reference code of the equipment information D2, which conceptually shows the equipment information D2. I'm just there.

By the way, the extraction of the sensor data by the sensor system 3 is performed, for example, during a sampling period of a certain length (for example, about one week, two weeks, or one month) after the completion of the facility F1. For example, the sensor terminal 31 is installed at the timing when the worker H1 enters the target space A1 such as a preview inspection (finishing inspection) performed at the time of completion, and the sensor terminal 31 is removed at the timing when the sampling period ends. As a result, sensor data for generating the equipment information D2 can be collected during the period when the equipment 9 is actually in operation, and the reliability of the equipment information D2 is improved.

(3) Data Generation Method Hereinafter, a data generation method using the data generation system 1 according to the present embodiment will be described with reference to FIGS. 3 to 5B.

First, the facility data D10 generated by the data generation method according to the present embodiment will be described. In the present embodiment, as shown in FIG. 3, the facility data D10 is data including the spatial information D1 and the equipment information D2, and is the data in which the spatial information D1 and the equipment information D2 are associated with each other. As an example, the association is performed by assigning the same identifier to the spatial information D1 and the equipment information D2.

Further, in the present embodiment, the facility data D10 includes position information indicating the installation position of the equipment 9 in the target space A1. In other words, the equipment information D2 of a certain equipment 9 includes the position information indicating the position (coordinate position) where the equipment 9 is installed in the target space A1. As a result, the equipment information D2 of the equipment 9 is associated with the same position as the position where the equipment 9 is installed even on the target space A1 represented by the space information D1. For example, the equipment information D2 about the air-conditioning equipment 91 installed in the living room is associated with the position corresponding to the living room in the spatial information D1 also in the facility data D10. On the other hand, for example, the equipment information D2 about the air-conditioning equipment 91 installed in the bedroom is associated with the position corresponding to the bedroom in the space information D1 also in the facility data D10. Therefore, in the facility data D10, the information of the equipment 9 can be managed including the installation position of the equipment 9.

Here, in the present embodiment, it is assumed that the facility data D10 is used for the maintenance of the facility F1, in particular, the maintenance of the facility 9 installed in the facility F1. Therefore, in the present embodiment, the equipment information D2 includes information used for the maintenance of the equipment 9. The information used for the maintenance of the equipment 9 may include, for example, information such as how the equipment 9 is used, the cumulative operating time, and the maintenance time. For example, if the air conditioner 91 is used only for cooling without being used for heating, it is suggested to replace the air conditioner 91 with an air conditioner 91 specialized for cooling performance when the air conditioner 91 is replaced. Etc. are possible. Further, for example, if the lighting equipment 92 is always used at a dimming level of 50%, it is possible to propose replacement with the lighting equipment 92 having a reduced output when the lighting equipment 92 is replaced. Is possible.

More specifically, in the present embodiment, the equipment information D2 includes characteristic information regarding at least one of the specifications, performance, and functions of the equipment 9. That is, the characteristic information is information that abstractly represents the characteristics required or expected of the equipment 9 in comparison with the product number or model number of the equipment 9. Therefore, from such characteristic information, for example, it becomes easy to identify the equipment 9 having the same performance or function as the existing equipment 9. In the present embodiment, the equipment information D2 may be generated based on the sensor data acquired from the target space A1 in which the equipment 9 is installed, and if it is the characteristic information regarding the specifications, performance, functions, etc. of the equipment 9. , Easy to identify. For example, in the case of the air conditioner 91, it is easy to specify the performance such as the cooling capacity or the heating capacity of the air conditioner 91 by the relationship between the size of the target space A1 and the temperature in the target space A1 when the air conditioner 91 is in operation. Further, for example, in the case of the lighting equipment 92, it is easy to specify the performance such as the output of the lighting equipment 92 by the relationship between the size of the target space A1 and the illuminance in the target space A1 when the lighting equipment 92 is in operation.

In particular, in the present embodiment, the equipment information D2 includes environmental information including information on the distribution of physical characteristics (temperature, humidity, atmospheric pressure, illuminance, air flow, etc.) in the target space A1. Then, there may be a correlation between the specifications, performance, or function of the equipment 9 and the distribution of the physical characteristics in the target space A1 when the equipment 9 is in operation. For example, in the case of the air conditioning equipment 91, the distribution of temperature and the distribution of airflow in the target space A1 during operation of the air conditioning equipment 91 differ depending on the specifications, performance, or function of the air conditioning equipment 91. Further, for example, in the case of the lighting equipment 92, the distribution of illuminance in the target space A1 when the lighting equipment 92 is in operation differs depending on the specifications, performance, or function of the lighting equipment 92. Therefore, the specifications, performance, functions, and the like of the equipment 9 can be specified from the equipment information D2 including the information regarding the distribution of the physical characteristics in the target space A1.

Further, in the present embodiment, the facility data D10 is data indicating at least the status related to the maintenance of the facility 9 by the combination of the spatial information D1 and the facility information D2. That is, in the present embodiment, as a result of combining both the spatial information D1 and the equipment information D2, the situation related to the maintenance of the equipment 9 is shown. For example, since the spatial information D1 alone does not provide information on the equipment 9, it does not naturally indicate the situation related to the maintenance of the equipment 9. On the other hand, since it is not possible to know what shape the target space A1 is installed in from the equipment information D2 alone, for example, when replacing the equipment 9, what size of the equipment 9 should be used, or the inspection equipment of the equipment 9. It is not possible to specify what kind of equipment should be brought in.

In addition, the equipment information D2 may include information that specifically identifies the equipment 9, such as the product number or model number of the equipment 9, installation time, power consumption, and the like.

Such facility data D10 is used in the construction (new construction) work of facility F1 because it is data that is assumed to be used for the maintenance of facility F1, especially the maintenance of equipment 9 installed in facility F1. Compared to BIM data and the like, the amount of information required is smaller. For example, if the BIM data is used in the construction (new construction) work of the facility F1, the information of the members necessary for the construction (installation and connection) of the equipment 9 is included, but if the facility data D10 in the present embodiment is used. , Information on such members is unnecessary.

FIG. 4 is a flowchart showing an example of the data generation method according to the present embodiment.

That is, first, for example, in addition to the preview inspection at the time of completion, the shape measurement system 2 executes three-dimensional measurement for measuring the shape of the target space A1 of the facility F1 (S1). Then, since the shape measurement system 2 generates the spatial information D1 based on the measurement data, the data generation system 1 acquires the spatial information D1 from the shape measurement system 2 by the first acquisition unit 11 (S2). ..

Next, during a sampling period of a certain length after completion, sensor data is acquired from the target space A1 in which the equipment 9 is installed by the plurality of sensor terminals 31 of the sensor system 3 installed in the facility F1 (S3). Then, when the sampling period ends, the sensor system 3 generates the equipment information D2 based on the sensor data. Therefore, the data generation system 1 acquires the equipment information D2 from the sensor system 3 by the second acquisition unit 12. (S4).

Next, the data generation system 1 generates facility data D10 by associating the acquired spatial information D1 with the equipment information D2 in the generation unit 13 (S5 to S10). Specifically, in the data generation system 1, first, the generation unit 13 extracts the equipment 9 from the spatial information D1 (S5). At this time, each of the extracted equipment 9 is given an identifier in the form of "nth equipment" (n is a natural number). The generation unit 13 sets the variable n to "1" (S6) and assigns the equipment information D2 to the nth equipment (here, the first equipment) in the spatial information D1 (S7). Then, the generation unit 13 determines whether or not the addition of the equipment information D2 is completed for all the equipment 9 extracted in the spatial information D1 (S8).

If the addition of the equipment information D2 is not completed (S8: No), the generation unit 13 increments the variable n (S9) and returns to the process S7. On the other hand, when the addition of the equipment information D2 to all the equipment 9 is completed (S8: Yes), the generation unit 13 stores (stores) the generated facility data D10 in the storage unit 17 (S10).

The flowchart of FIG. 4 is merely an example of a data generation method, and the processing may be omitted or added as appropriate, or the order of the processing may be changed as appropriate.

5A and 5B are explanatory views conceptually showing the process of generating the facility data D10.

That is, since the shape of the target space A1 is reflected in the space information D1, as shown in FIG. 5A, a protrusion of the shape of the air conditioning equipment 91 occurs on the wall on which the air conditioning equipment 91 is installed. Therefore, the generation unit 13 recognizes such a protruding shape as the equipment 9, and extracts the equipment 9 from the spatial information D1 (S5). Then, the generation unit 13 assigns the equipment information D2 to the extracted air conditioning equipment 91 (S7). As a result, in the target space A1 on the space information D1, as shown in FIG. 5B, the equipment information D2 is attached to the air conditioning equipment 91, and the space information D1 and the equipment information D2 are associated with each other. To.

By executing the same process for all the extracted facilities 9, the association between the spatial information D1 and the facility information D2 is completed, and the facility data D10 is generated.

(4) Example of Utilization of Facility Data Hereinafter, an example of utilization of facility data D10 generated by the data generation system 1 according to the present embodiment will be described with reference to FIGS. 6A and 6B.

In the present embodiment, the data generation system 1 outputs display data for displaying the facility data D10 by the display output unit 14. The display output unit 14 transmits the display data to the information terminal 4, so that the information terminal 4 can display the facility data D10.

That is, as shown in FIG. 6A, the display unit 41 of the information terminal 4 displays an image (screen) including the facility data D10 transmitted (distributed) from the display output unit 14 of the data generation system 1. The information terminal 4 has a touch panel display, and the display unit 41 also functions as an input unit for receiving the operation of the worker H1. As a result, the worker H1 can confirm the facility data D10 of the facility F1 by looking at the screen displayed on the information terminal 4, as shown in FIG. 6A. Specifically, in the example of FIG. 6A, the floor plan of the facility F1 based on the spatial information D1 and the icon D11 of the facility 9 based on the facility information D2 are displayed as the facility data D10 on the information terminal 4. .. In the present embodiment, the facility data D10 is divided into two layers of data, the floor plan based on the spatial information D1 is displayed as the basic layer, and the icon D11 of the equipment 9 based on the equipment information D2 is superimposed on the basic layer. It is displayed as a superposed layer. That is, the spatial information D1 and the equipment information D2 are displayed on different layers. As a result, the worker H1 can confirm the floor plan of the facility F1 and what kind of equipment 9 is installed in the facility F1 on the screen of the information terminal 4.

Then, as shown in FIG. 6A, when the worker H1 taps the icon D11 of the air conditioning equipment 91 to give the information terminal 4 an input for selecting the icon D11, a screen as shown in FIG. 6B is displayed. Switch to. In the example of FIG. 6B, a part of the facility F1 including the equipment 9 (here, the air conditioning equipment 91) corresponding to the tapped icon D11 is enlarged and displayed, and the equipment information D2 related to the equipment 9 is displayed on the enlarged display. There is. In the example of FIG. 6B, the equipment information D2 includes explanatory information D21 relating to the description of the equipment 9 and characteristic information D22 relating to the characteristics of the equipment 9. The explanatory information D21 includes information such as the cooling capacity or the heating capacity of the air conditioner 91, and is displayed in a balloon displayed superimposed on the floor plan (spatial information D1) of the facility F1. The characteristic information D22 represents the distribution of the airflow generated by the air conditioner 91 in the target space A1, and is displayed superimposed on the floor plan (spatial information D1) of the facility F1.

A screen as illustrated in FIG. 6B will be displayed for each piece of equipment 9. That is, when the icon of the lighting equipment 92 is tapped on the screen of FIG. 6A, the equipment information D2 relating to the lighting equipment 92 is displayed.

(5) Modified Example The first embodiment is only one of the various embodiments of the present disclosure. The first embodiment can be changed in various ways depending on the design and the like as long as the object of the present disclosure can be achieved. Each figure described in the present disclosure is a schematic view, and the ratio of the size and the thickness of each component in each figure does not necessarily reflect the actual dimensional ratio. Further, the same function as the data generation system 1 according to the first embodiment may be realized by a data generation method, a computer program, a non-temporary recording medium on which the computer program is recorded, or the like. The data generation method according to one aspect includes a first acquisition process (corresponding to “S2” in FIG. 4), a second acquisition process (corresponding to “S4” in FIG. 4), and a generation process (corresponding to “S5” in FIG. 4). Corresponds to "S10") and. The first acquisition process is a process of acquiring spatial information regarding the shape of the target space of the facility. The second acquisition process is a process for acquiring equipment information regarding the equipment installed in the target space. The generation process is a process of generating facility data by associating the spatial information with the equipment information. The (computer) program according to one aspect is a program for causing one or more processors to execute the above data generation method.

Hereinafter, modifications of the first embodiment will be listed. The modifications described below can be applied in combination as appropriate.

The data generation system 1 in the present disclosure includes a computer system. The main configuration of a computer system is a processor and memory as hardware. When the processor executes the program recorded in the memory of the computer system, the function as the data generation system 1 in the present disclosure is realized. The program may be pre-recorded in the memory of the computer system, may be provided through a telecommunications line, and may be recorded on a non-temporary recording medium such as a memory card, optical disk, hard disk drive, etc. that can be read by the computer system. May be provided. A processor in a computer system is composed of one or more electronic circuits including a semiconductor integrated circuit (IC) or a large scale integrated circuit (LSI). The integrated circuit such as IC or LSI referred to here has a different name depending on the degree of integration, and includes an integrated circuit called a system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). Further, an FPGA (Field-Programmable Gate Array) programmed after the LSI is manufactured, or a logical device capable of reconfiguring the junction relationship inside the LSI or reconfiguring the circuit partition inside the LSI should also be adopted as a processor. Can be done. A plurality of electronic circuits may be integrated on one chip, or may be distributed on a plurality of chips. The plurality of chips may be integrated in one device, or may be distributed in a plurality of devices. The computer system referred to here includes a microprocessor having one or more processors and one or more memories. Therefore, the microprocessor is also composed of one or a plurality of electronic circuits including a semiconductor integrated circuit or a large-scale integrated circuit.

Further, it is not essential for the data generation system 1 that at least a part of the functions of the data generation system 1 are integrated in one housing, and the components of the data generation system 1 are in a plurality of housings. It may be provided in a dispersed manner. For example, the first acquisition unit 11, the second acquisition unit 12, and the generation unit 13 of the data generation system 1 may be provided in a housing different from the display output unit 14 and the data output unit 15. Further, at least a part of the functions of the data generation system 1 may be realized by a cloud (cloud computing) or the like.

On the contrary, in the first embodiment, at least a part of the functions distributed in a plurality of devices may be integrated in one housing. For example, at least one of the function of generating the spatial information D1 of the shape measurement system 2 and the function of generating the equipment information D2 of the sensor system 3 may be integrated in the data generation system 1.

In the first embodiment, the data generation system 1 does not include the shape measurement system 2 and the sensor system 3 as components. However, at least one of the shape measurement system 2 and the sensor system 3 may be included in the components of the data generation system 1.

Further, it is not essential that the data generation system 1 includes all of the first acquisition unit 11, the second acquisition unit 12, the generation unit 13, the display output unit 14, the data output unit 15, the update unit 16, and the storage unit 17. .. For example, at least one of the display output unit 14, the data output unit 15, the update unit 16, and the storage unit 17 can be omitted as appropriate.

Further, the use of the facility data D10 (see FIG. 3) generated by the data generation system 1 is not limited to the maintenance of the facility F1 (including the maintenance of the equipment 9). For example, based on the facility data D10, it is possible to recommend to the manager of the facility F1 in which the certain facility 9 is installed, a substitute facility having the same function as the certain facility 9. Alternatively, for example, the facility data D10 of a certain facility F1 can be used even when constructing (newly constructing) a facility having the same specifications as the certain facility F1, including the specifications and functions of the facility 9.

Further, the spatial information D1 is not limited to the information regarding the three-dimensional shape of the target space A1, and may be, for example, information regarding the two-dimensional shape of the target space A1.

Further, the mode of output of the facility data D10 generated by the data generation system 1 is not limited to the output (transmission) to the information terminal 4 and the data processing system 5. For example, the data generation system 1 may output (transmit) the facility data D10 to a system other than the information terminal 4 and the data processing system 5 by communication, or write the facility data D10 to a non-temporary recording medium and write it to a non-temporary recording medium. It may be output in the form of printout or the like. Further, the data generation system 1 outputs facility data D10 to a person (worker, etc.) by means such as display, sound (including voice and alarm sound) output, optical output (including blinking, etc.), and printout. May be output (presented) to.

Further, it is not essential for the shape measurement system 2 to generate the spatial information D1 at the measurement terminal 21. For example, the measurement terminal 21 may only measure the measurement data, the measurement terminal 21 may transmit the measurement data to a higher-level system such as a server, and the higher-level system may generate spatial information D1 from the measurement data.

(Embodiment 2)
As shown in FIG. 7, the data generation system 1A according to the present embodiment is different from the data generation system 1 according to the first embodiment in that it includes an estimation unit 18. Hereinafter, the same configurations as those in the first embodiment are designated by common reference numerals, and the description thereof will be omitted as appropriate.

That is, the data generation system 1A according to the present embodiment includes the first acquisition unit 11, the second acquisition unit 12, the generation unit 13, the display output unit 14, the data output unit 15, the update unit 16, and the storage unit 17. The estimation unit 18 is further provided.

The estimation unit 18 estimates the state of the facility F1 based on the equipment information D2 acquired by the second acquisition unit 12 from the sensor system 3. The term "estimate" as used in the present disclosure means to make a decision (decision), and in particular, it is not limited to a person making a decision by thinking about it, but also includes making a decision based on a certain fact. Therefore, for example, when input information is input to a computer system, if the computer system performs a calculation based on the input information and outputs some information as output information, the output information is "" in the computer system. It has been "estimated". That is, in the estimation unit 18, the equipment information D2 is input, and the state of the facility F1 is estimated based on the equipment information D2.

The estimation unit 18 basically estimates the state of the facility F1 which is difficult to measure with the shape measurement system 2. As an example, the estimation unit 18 estimates the concealed wiring (preceding wiring), concealed piping (preceding piping), wall thickness, or the material of a structure such as a wall, floor, pillar, or ceiling in the facility F1.

For example, if the equipment 9 is an outlet as a wiring fixture installed on the wall, the estimation unit 18 tells that there is a 100V or 200V power line behind the wall on which the equipment 9 is installed. Can be estimated. In particular, if the outlet is connected to the 200V type air conditioning equipment 91, it can be estimated by the estimation unit 18 that a 200V power line exists behind the wall where the equipment 9 (outlet) is installed. Is. Further, as another example, if the equipment 9 is a washing machine, it can be estimated by the estimation unit 18 that there is a pipe for water supply and a pipe for drainage in the vicinity thereof.

The estimation result by the estimation unit 18 is included in the facility data D10. That is, the generation unit 13 generates the facility data D10 including the estimation result of the estimation unit 18, and stores (stores) it in the storage unit 17.

Further, in the present embodiment, the first acquisition unit 11 acquires the spatial information D1 from the database 7 instead of the shape measurement system 2. That is, instead of the data generated by actually measuring the facility F1 at the measurement terminal 21 of the shape measurement system 2 as in the first embodiment, the BIM data or the like stored in the database 7 is used as the spatial information D1. The first acquisition unit 11 acquires. The spatial information D1 (BIM data, etc.) stored in the database 7 is, for example, data created at the time of construction (new construction) of facility F1. Therefore, in the present embodiment, the shape measurement system 2 can omit the three-dimensional measurement process (“S1” in FIG. 4) for measuring the shape of the target space A1 of the facility F1.

Further, in the second embodiment, it is not essential for the first acquisition unit 11 to acquire the spatial information D1 from the database 7, and as in the first embodiment, the first acquisition unit 11 receives the spatial information D1 from the shape measurement system 2. May be obtained.

The various configurations (including the modified examples) described in the second embodiment can be appropriately combined with the various configurations (including the modified examples) described in the first embodiment.

(Summary)
As described above, the data generation system (1,1A) according to the first aspect includes a first acquisition unit (11), a second acquisition unit (12), and a generation unit (13). The first acquisition unit (11) acquires spatial information (D1) regarding the shape of the target space (A1) of the facility (F1). The second acquisition unit (12) acquires the equipment information (D2) regarding the equipment (9) installed in the target space (A1). The generation unit (13) generates facility data (D10) by associating spatial information (D1) with equipment information (D2).

According to this aspect, in the facility data (D10), the spatial information (D1) regarding the shape of the target space (A1) of the facility (F1) and the equipment installed in the target space (A1) of the facility (F1) (A1). The equipment information (D2) related to 9) is linked. Such facility data (D10) can be used not only for the maintenance of the facility (F1) itself, but also for the maintenance of the equipment (9) installed in the facility (F1). Therefore, for example, in the maintenance of the facility (F1), the facility data (D10) is used to actually confirm the site such as what kind of equipment (9) is installed in the facility (F1). The time and effort required for this is reduced. As a result, it is possible to reduce the work load related to the maintenance of the facility (F1).

In the data generation system (1,1A) according to the second aspect, in the first aspect, the equipment information (D2) includes information used for maintenance of the equipment (9).

According to this aspect, by using the facility data (D10), it is possible to reduce the work load related to the maintenance of the equipment (9).

In the data generation system (1,1A) according to the third aspect, in the first or second aspect, the equipment information (D2) is the sensor data acquired from the target space (A1) in which the equipment (9) is installed. Includes environmental information based on.

According to this aspect, the information about the equipment (9) in the state where the equipment (9) is actually installed in the target space (A1) can be reflected in the facility data (D10).

In the data generation system (1,1A) according to the fourth aspect, in the third aspect, the environmental information includes information regarding the distribution of physical characteristics in the target space (A1).

According to this aspect, the information regarding the distribution of the physical characteristics actually given to the target space (A1) by the equipment (9) can be reflected in the facility data (D10).

In the data generation system (1,1A) according to the fifth aspect, in any one of the first to fourth aspects, the spatial information (D1) is information regarding the three-dimensional shape of the target space (A1).

According to this aspect, the shape of the target space (A1) can be expressed in detail in the facility data (D10) as compared with the case where the spatial information (D1) is the information related to the two-dimensional shape.

In the data generation system (1,1A) according to the sixth aspect, in any one of the first to fifth aspects, the facility data (D10) determines the installation position of the equipment (9) in the target space (A1). Includes the location information to be represented.

According to this aspect, facility data (D10) that distinguishes the installation positions of the equipment (9) in the target space (A1) can be generated.

In the data generation system (1,1A) according to the seventh aspect, in any one of the first to sixth aspects, the equipment information (D2) relates to at least one of the specifications, performance, and functions of the equipment (9). Contains characteristic information.

According to this aspect, it becomes easy to identify, for example, equipment (9) having the same performance or function as the existing equipment (9) from the characteristic information.

In the data generation system (1,1A) according to the eighth aspect, in any one of the first to seventh aspects, the equipment (9) is installed in a fixed position of the facility (F1). ..

According to this aspect, the information of the equipment (9) highly related to the facility (F1) can be reflected in the facility data (D10).

In the data generation system (1,1A) according to the ninth aspect, in any one of the first to eighth aspects, the spatial information (D1) is generated based on the measurement data measured at the facility (F1). Information.

According to this aspect, the shape of the target space (A1) in which the equipment (9) is actually installed can be reflected in the facility data (D10).

In the data generation system (1,1A) according to the tenth aspect, in any one of the first to ninth aspects, the facility data (D10) is based on the combination of the spatial information (D1) and the equipment information (D2). It is data showing at least the situation concerning maintenance of equipment (9).

According to this aspect, as a result of combining both the spatial information (D1) and the equipment information (D2), the situation related to the maintenance of the equipment (9) can be shown.

The data generation system (1,1A) according to the eleventh aspect has a display output unit (14) that outputs display data for displaying the facility data (D10) in any one of the first to tenth aspects. Further prepare.

According to this aspect, the facility data (D10) can be output in a visible manner.

The data generation system (1,1A) according to the twelfth aspect is the data processing system (5) that executes a predetermined process using the facility data (D10) in any one of the first to eleventh aspects. A data output unit (15) for outputting facility data (D10) is further provided.

According to this aspect, the facility data (D10) can be used for a predetermined process such as a simulation.

The data generation method according to the thirteenth aspect includes a first acquisition process, a second acquisition process, and a generation process. The first acquisition process is a process of acquiring spatial information (D1) regarding the shape of the target space (A1) of the facility (F1). The second acquisition process is a process for acquiring equipment information (D2) related to the equipment (9) installed in the target space (A1). The generation process is a process of generating facility data (D10) by associating spatial information (D1) with equipment information (D2).

According to this aspect, it is possible to reduce the work load related to the maintenance of the facility (F1).

The program according to the fourteenth aspect is a program for causing one or more processors to execute the data generation method according to the thirteenth aspect.

According to this aspect, it is possible to reduce the work load related to the maintenance of the facility (F1).

Not limited to the above aspects, various configurations (including modifications) of the data generation system (1,1A) according to the first and second embodiments can be embodied by a data generation method or a program.

The configuration according to the second to twelfth aspects is not an essential configuration for the data generation system (1,1A) and can be omitted as appropriate.

1,1A Data generation system 5 Data processing system 9 Equipment 11 1st acquisition unit 12 2nd acquisition unit 13 Generation unit 14 Display output unit 15 Data output unit A1 Target space D1 Spatial information D2 Equipment information D10 Facility data F1 Facility

Claims (14)

The first acquisition department that acquires spatial information about the shape of the target space of the facility,
The second acquisition unit that acquires equipment information about the equipment installed in the target space, and
A generation unit that generates facility data by associating the spatial information with the equipment information is provided.
Data generation system. The equipment information includes information used for maintenance of the equipment.
The data generation system according to claim 1. The equipment information includes environmental information based on sensor data acquired from the target space in which the equipment is installed.
The data generation system according to claim 1 or 2. The environmental information includes information on the distribution of physical characteristics in the target space.
The data generation system according to claim 3. The spatial information is information regarding the three-dimensional shape of the target space.
The data generation system according to any one of claims 1 to 4. The facility data includes position information indicating the installation position of the equipment in the target space.
The data generation system according to any one of claims 1 to 5. The equipment information includes characteristic information regarding at least one of the specifications, performance, and functions of the equipment.
The data generation system according to any one of claims 1 to 6. The equipment is installed in a fixed position in the facility.
The data generation system according to any one of claims 1 to 7. The spatial information is information generated based on the measurement data measured at the facility.
The data generation system according to any one of claims 1 to 8. The facility data is data indicating at least a situation related to maintenance of the facility by combining the spatial information and the facility information.
The data generation system according to any one of claims 1 to 9. A display output unit for outputting display data for displaying the facility data is further provided.
The data generation system according to any one of claims 1 to 10. A data output unit that outputs the facility data to a data processing system that executes a predetermined process using the facility data is further provided.
The data generation system according to any one of claims 1 to 11. The first acquisition process to acquire spatial information about the shape of the target space of the facility,
The second acquisition process to acquire equipment information about the equipment installed in the target space, and
It has a generation process for generating facility data by associating the spatial information with the equipment information.
Data generation method. A program for causing one or more processors to execute the data generation method according to claim 13.

Images