RU2573264C1 - Hardware and software system for managing innovative development of oil extraction and processing enterprise - Google Patents

Abstract

FIELD: physics; control.

SUBSTANCE: invention relates to a hardware and software system for managing innovative development of an oil extraction and processing enterprise. The system comprises a digital data transmission channel, a server with a software module of a model for evaluating efficiency and monitoring implementation of innovative projects for managing innovative development of the enterprise using simulation algorithms, peripheral automated control workstations, automated expert evaluation workstations and automated workstations for inputting actual data during monitoring, a communication channel, wherein the software module comprises sub-program modules of a model of the enterprise, a model of innovative development of the enterprise, a data storage, computation, creating knowledge maps and rendering, collecting data on ambient parameters, event analysis, setting the level of detail of reports, scenario planning and real-time adjustment of parameters of the model of innovative development of the enterprise.

EFFECT: automating innovative development management.

2 cl, 40 dwg

Description

The invention relates to systems for distributed management of enterprises in the field of oil production and refining and, preferably, can be used for the management of innovative development of these enterprises when they introduce innovative technical solutions.

The prior art integrated automated information-analytical system for integrated enterprise management (patent for utility model of the Russian Federation No. 16877, IPC: G06F 17/60, publ. 02.20.2001). The specified system contains an automated subsystem for operational management of the enterprise, which includes automated workstations (AWS), including AWP "Personnel" complementing each other, and an automated subsystem for controlling the technological process, interconnected feedback channels. The known system has a database, as well as an information and analytical subsystem for strategic management, which contains sequentially connected automated workplaces for a marketer, automated workplaces for analyzing stock indicators, automated workplaces for analyzing stock markets, automated workplaces for analyzing media and automated workplaces for analyzing the environment and data storage. In turn, the data warehouse includes a database of business activity analysis indicators (AChED) of the enterprise, as well as databases of scientific and technical projects and development of the product range, price databases, customer databases, databases of enterprise suppliers and similar competitor databases.

The system under consideration also has a comparison unit, an advantage assessment unit, a strategy selection unit and a strategy analysis and implementation unit, consisting of an analyst workstation, a manager’s workstation and strategic planning workstation, while the second input of the benefit assessment unit is connected to the enterprise’s ACAD database, which is connected with an automated information and analytical subsystem for operational management. The latter contains the operational management unit, which is associated with the output of the analysis and implementation of the strategic management subsystem strategy block, which includes the Finance automated workstation, the Accountancy automated workstation, the Economist automated workplace, the production manager automated workplace, and operational planning workstation, which are also connected to the operational data storage. The operational data warehouse consists of databases of supply deliveries, raw materials, semi-finished products, technological operations, production schedule, orders, logistics operations, suppliers of finished data products, and they are interconnected with the process control unit, which includes supply workstation, workstation OTC, warehouse workstation, workstation AWP, dispatcher workstation, master workstation, warehouse workstation and sales workstation, also included in the automatic information subsystem for process control, including In addition, there is a universal hub, the inputs of which are connected to the outputs of the measurement, control and control sensors connected to the production modules, and the outputs are connected to the workstation of the technologist, dispatcher workstation and master workstation, while the workstation AWS and warehouse workstations are connected to the control and measuring equipment of the raw material warehouses and materials and a finished goods warehouse, respectively, while all the nodes and blocks of the system are connected by a local computer network, and the workstations are based on personal computers and are used along with the standard ogrammnym software expert systems.

The disadvantage of the analogue is the relatively low level of performance due to the complex technology of managerial decision-making (based on multi-aspect and multivariate modeling and analysis) and the inability to use the analogue to manage the innovative development of the enterprise.

The closest in technical essence and the achieved result to the proposed device is an automated information-analytical system for monitoring projects (patent for utility model of the Russian Federation No. 91198, IPC G06F 17/00, published on 10/27/2010, Bull. No. 3). This system is formed from workstations (AWS) of various departments of the enterprise, including planning, developing design and technological documentation (CD and TD), production and providing units that are connected to the control unit via data and control buses with the ability to exchange information, at the same time, the analytical reporting subsystem (PAO) is included in the structure of the system under consideration. Structurally, the PJSC consists of a module for displaying the status of projects (ISMT), made with the possibility of presenting reporting information on projects with the necessary level of detail, a module for monitoring performance (MKI), made with the possibility of presenting administrative documents and information about their implementation, and associated with data buses and management with the ability to exchange information of the data acquisition module (MSD).

At the same time, the first and second inputs and outputs of the MSD are connected, respectively, with the inputs and outputs of the MOSP and MKI, as well as information-switching connected to the data and control buses of the workstation of the control unit for the execution of administrative documents. The described automated information-analytical system for monitoring projects is adopted as a prototype.

The disadvantage of the prototype is the relatively low level of performance, due to the need to assess the current state of affairs (and, accordingly, the subsequent adoption of a managerial decision) based on the form of information display in the form of a set of work indicators, as well as the inability to use the prototype device to manage the innovative development of the enterprise.

The task to which the proposed hardware and software complex is aimed is to create an automated tool for managing the innovative development of the enterprise in the field of oil production and refining.

The technical result expected from the use of the proposed hardware-software complex is to increase the speed and the possibility of its use to manage the innovative development of the enterprise.

The claimed technical result is achieved by the fact that the hardware-software complex for managing the innovative development of the enterprise in the field of oil production and refining consists of a server equipped with an input / output connected to a digital data transmission channel with a software module for the model for evaluating the effectiveness and monitoring of implementation innovative projects for managing the innovative development of the enterprise using simulation algorithms and peripheral AWP management, AWP examination and AWP arm Yes, the actual data is in the process of monitoring, the inputs / outputs are also connected to a digital data transmission channel, and the mentioned software module is formed from a subprogram module of the enterprise model, the input / output of which is connected to the information and switching bus of the server, the subprogram module of the enterprise innovative development model, input / the output of which is connected to the information and switching bus of the server, the sub-program module of the data warehouse, the input / output of which is connected to the information and switching bus of the server RA, subroutine calculation module, the input / output of which is connected to the information and switching bus of the server, subroutine module for generating knowledge and visualization cards, the input / output of which is connected to the information and switching bus of the server, the subroutine module for collecting data on environmental parameters, input / output which is connected to the information and switching bus of the server, subroutine module of event analytics, the input / output of which is connected to the information and switching bus of the server, subroutine module the level of detail of reports, the input / output of which is connected to the information and switching bus of the server, the subroutine module of scenario planning, the input / output of which is connected to the information and switching bus of the server, and the subprogram module of operational adjustment of the parameters of the model of innovative development of the enterprise, the input / output of which is connected to the server information and switching bus.

It is preferable that the Internet be used in the hardware-software complex as a digital data transmission channel.

The list of positions:

1. AWP management.

2. AWP examination.

3. AWP of input of actual data during the monitoring process.

4. The server.

4.1. The program module "Model for evaluating the effectiveness and monitoring of the implementation of innovative projects to manage the innovative development of the enterprise using simulation algorithms":

4.1.1. Information and server switching bus.

4.1.2. Subroutine module of the enterprise model.

4.1.3. Subroutine module of the model of innovative development of the enterprise.

4.1.4. Subprogram module of the data warehouse.

4.1.5. Subprogramming calculation module.

4.1.6. Subprogramme module for the formation of knowledge cards and visualization.

4.1.7. Subroutine module for collecting data on environmental parameters.

4.1.8. Subroutine module of event analytics.

4.1.9. Subroutine module for setting the level of detail of reports.

4.1.10. Subroutine scenario planning module.

4.1.11. The subprogramme module for the operational adjustment of the parameters of the model of innovative development of the enterprise.

4.2. A means of connecting a server to a digital data channel.

5. Digital data transmission channel.

6. Communication channels of subprogram modules.

6.1. The communication channel of the subprogram module of the enterprise model with the information and switching bus of the server.

6.2. The communication channel of the subprogram module of the model of innovative development of the enterprise with the information and switching bus of the server.

6.3. The communication channel of the data storage routine module with the server information and switching bus.

6.4. Communication channel of the subprogramming calculation module with the information and switching bus.

6.5. The communication channel of the subprogramme module for generating knowledge and visualization cards with the information and switching bus.

6.6. The communication channel of the sub-program module for collecting data on environmental parameters with the information and switching bus.

6.7. Communication channel of the event analytics module with the information and switching bus.

6.8. The communication channel of the subroutine module for setting the level of detail of reports with the information and switching bus of the server.

6.9. Communication channel of the scenario programming subroutine module with the server information and switching bus.

6.10. Communication channel for the operational adjustment of the parameters of the enterprise innovative development model with the server information and switching bus.

As an automated workstation (AWP) of control 1 (Fig. 1), a PC compatible personal computer with, for example, the Windows XP operating system (or Windows 8) and the Microsoft SharePoint Designer 2010 software product can be used.

As an AWP examination 2 (Fig. 1), a PC compatible personal computer with, for example, the Windows XP operating system (or Windows 8) and the Microsoft SharePoint Designer 2010 software product can be used.

As a workstation for inputting actual data during monitoring 3 (Fig. 1), a PC compatible personal computer with, for example, the Windows XP operating system (or Windows 8) and the Microsoft SharePoint Designer 2010 software product can be used.

The difference between the workstations mentioned above is the access level. AWP management 1 (Fig. 1) has access to server 4 (Fig. 1) and, accordingly, all software and subprogram modules installed on it without authorization, AWP of expertise 2 (Fig. 1) has access to server 4 (Fig. 1). 1) and, accordingly, all software and subprogram modules installed on it, only with permission to access it from the workstation 1 (Fig. 1), and the workstation for entering actual data during monitoring 3 (Fig. 1) has only the ability to transmit to the server 4 (Fig. 1) digital data associated with the degree of completion of concre deleterious innovative project at the current time.

As the server 4 (Fig. 1) can be used a server company Hewlett-Packard, in particular HP ProLiant DL 580 R07. Microsoft Server Server 2008R2 Enterprise, Microsoft SharePoint 2010 Server, and Microsoft SharePoint Designer 2010 are installed on the server.

In addition to installing the above computer programs, server 4 (Fig. 1) installs the original software product “Model for evaluating the effectiveness and monitoring of the implementation of innovative projects for managing the innovative development of an enterprise using simulation algorithms” (Certificate of state registration of a computer program No. 20144612617) , which forms the software module of the same name 4.1 (Fig. 1).

The installation of the computer program "Model for evaluating the effectiveness and monitoring the implementation of innovative projects for managing innovative development of the enterprise using simulation algorithms" on server 4 (Fig. 1) and the formation of software module 4.1 on it (Fig. 1) is accompanied by the creation of a number of subprogram modules, input -the output of each of which is connected to the information and switching bus 4.1.1 (Fig. 1) through the corresponding communication channel of the subprogram modules 6 (Fig. 1), namely:

- the subprogram module of the enterprise model 4.1.2 (Fig. 1), the main functions of which are the formation of a request for data on the parameters of the business processes of the enterprise and updating the data, i.e. the introduction (or exclusion) of the enterprise value chain process, the introduction (or exclusion) of the enterprise value chain product, the introduction (or exclusion) of a specific indicator, the updating of indicator values (for indicator values previously entered into the enterprise model) and the introduction of indicator values (for again entered indicators);

- subroutine module of the model of innovative development of the enterprise 4.13 (Fig. 1), the main functions of which are the formation of a request for data on the parameters of innovative development of the enterprise and updating the following information: data on the goal and task of innovative development from the point of view of influence on the main (production) business processes , data on the target values of KPIs (key performance indicators) of innovative development, data on targeted technologies, the development of which is expected due to innovative development of measures, KPI data reflecting the target degree of development of target technologies, data on the target level of quality of marketable products, the development of which is expected due to the innovative development of the enterprise, data on target dates for achieving the KPI of innovative development of the enterprise, data on budgets planned for development aimed at achieving specific KPIs of innovative development of the enterprise;

- a sub-program module of the data warehouse 4.1.4 (Fig. 1), the main functions of which are to store the enterprise model and the model of innovative development of the enterprise, to store the data model in the form of a file storage that makes it possible to store, search and establish the relationship between various types of information, for example documents , images, videos, etc., while the types of information can be considered as units of information that can be represented as cases of complex types that are part of systems s types that support inheritance. Inheritance can be defined as a situation in which certain characteristics move from one context to another. So, in the case of object-oriented programming, objects inherit attributes and / or behavior from other objects. Obviously, inheritance can be considered as a hierarchical structure and / or format. A data warehouse can store type examples and a query for efficiently and effectively locating at least one of: elements, documents, and / or contacts. It is capable of receiving data, which may include type, criteria, design, query criteria ... In particular, storing an instance of a type related to an information type (for example, a document, image, video, contact, message, email, sound fragment), may provide at least one of the following options:

1) finding in the data model of the file storage of at least one element that meets certain criteria;

2) the location in the data model of the file storage of at least one document that meets particular criteria.

A data warehouse can use relational database methods that relate to relational storage and relational query. Relational database methods can be associated with relational databases, in which a relational database is a collection of data elements organized as a set of formally described tables. The data in the tables can be accessed and / or reassembled in various ways, without requiring reorganization of the database tables. In addition, the relational database can be easily expanded, for example, by adding new categories without modifications to existing applications and / or data;

- subroutine calculation module 4.1.5 (Fig. 1), the main function of which is the calculation of indicator values in accordance with the calculation algorithms;

- a subprogramme module for generating knowledge and visualization cards 4.1.6 (Fig. 1), the main functions of which are the transformation of the calculation model data into visual images in accordance with the notation, which allows to identify the type of object (product / value chain process, innovative product, indicator) , type of indicator (financial, economic, operational, functional, technical), type of indicator (calculated, primary), the presence of deviations, the degree of significance of deviations (critical, significant, permissible) and the reasons for deviations;

- subroutine module for collecting data on environmental parameters 4.1.7 (Fig. 1), the main functions of which are requesting data on environmental parameters, and updating data on environmental parameters, including the introduction (or exclusion) of new indicators characterizing the external environment, updating the values of indicators characterizing the external environment (for indicators that were previously entered into the model) and entering the values of indicators (for newly introduced indicators characterizing the external environment);

- subroutine module for event analytics 4.1.8 (Fig. 1), the main function of which is to request updated data (on the progress of the project, on the internal environment and on the external environment);

- subroutine module for setting the level of detail of reports 4.1.9 (Fig. 1), the main function of which is to determine the level of detail of reports;

- a subprogramme module of scenario planning 4.1.10 (Fig. 1), the main function of which is to calculate the planned values of the project indicators for the analyzed scenarios and compare possible scenarios according to indicators selected in accordance with the methodology;

- a subprogramme module for the operational adjustment of the parameters of the enterprise innovative development model 4.1.11 (Fig. 1), the main function of which is the updating of model parameters (objects, indicators, relationships (calculation algorithms) and primary indicators).

The invention is illustrated by drawings:

- in FIG. 1 schematically shows a block diagram of a hardware-software complex for managing the innovative development of an enterprise in the field of oil production and hydrocarbon processing;

- in FIG. 2 is a graphical representation of an enterprise model as applied to oil production;

- in FIG. 3 shows a graphical interface of the model of innovative development of the enterprise in relation to oil production;

- in FIG. 4 is a graphical representation of a subroutine calculation module as applied to oil production;

- in FIG. 5 shows a graphical interface image of a subprogramme module for generating knowledge and visualization maps in relation to oil production;

- in FIG. 6 is a graphical representation of a subroutine module for collecting data on environmental parameters in relation to oil production;

- in FIG. 7 is a graphical representation of a subroutine module of event analytics in relation to oil production;

- in FIG. 8 is a graphical representation of the subroutine module for setting the level of detail of reports in relation to oil production;

- in FIG. 9 is a graphical representation of the scenario programming subroutine module as applied to oil production;

- in FIG. 10 is a graphical representation of the subprogramme module for the operational adjustment of the parameters of the enterprise innovative development model in relation to oil production;

- in FIG. 11 is an image of a graphical interface of an enterprise model as applied to oil (hydrocarbon) processing;

- in FIG. 12 is an image of a graphical interface of an enterprise innovative development model as applied to oil (hydrocarbon) processing;

- in FIG. 13 is a graphical representation of a subroutine calculation module as applied to oil (hydrocarbon) processing;

- in FIG. 14 is an image of a graphical interface of a subprogramme module for generating knowledge and visualization maps as applied to oil (hydrocarbon) processing;

- in FIG. 15 is a graphical representation of a subroutine module for collecting data on environmental parameters as applied to oil (hydrocarbon) processing;

- in FIG. 16 is a graphical representation of the subroutine module of event analytics in relation to the processing of oil (hydrocarbons);

- in FIG. 17 is a graphical representation of a subroutine module for setting the level of detail of reports in relation to oil (hydrocarbon) processing;

- in FIG. 18 is an image of a graphical interface of a routine scenario planning module for oil (hydrocarbon) processing;

- in FIG. Figure 19 shows a graphical interface image of a subprogram module for the operational adjustment of the parameters of the enterprise innovative development model as applied to oil (hydrocarbon) processing.

Example No. 1

As an illustration of the practical implementation of the proposed hardware and software complex in the field of oil production, we will use the innovation “Pump packer unit for simultaneous and separate operation of two layers” (see RF invention No. 2493359, IPC: Е21В 43/14, publ. September 20, 2013 g., Bull. No. 26).

After installing the above-mentioned software products on AWP 1-3 (Fig. 1) and server 4 (Fig. 1), a graphical interface is visualized for the user on the AWP control 1 (Fig. 1) in accordance with Figs. 2 formed by the subroutine module of the enterprise model 4.1.2 (Fig. 1). This subroutine module is connected to the control workstation 1 (Fig. 1), information and switching interacting with the digital data channel 5 (Fig. 1), through the communication channel 6.1 (Fig. 1) connected to the information and switching bus 4.1.1 ( Fig. 1), which, in turn, is also information-switching through the server interface means 4.2 (Fig. 1) connected to the mentioned digital data channel 5 (Fig. 1).

By sequentially manipulating widgets on the graphical interface visualized on the display of the workstation 1 (FIG. 1) in accordance with FIG. 2 and entering information about the enterprise (i.e. updating the data on the process of the value chain of the enterprise, updating the data on the product of the value chain of the enterprise, etc.), form a specific model of the enterprise, which is saved due to the transfer of data via the 6.1 communication channel ( Fig. 1), the information and communication bus 4.1.1 (Fig. 1) and the communication channel 6.3 (Fig. 1) through the subroutine module 4.1.4 (Fig. 1) in the data warehouse.

Then, from the control workstation 1 (Fig. 1) via the digital data transmission channel 5 (Fig. 1), through the interface means 4.2 (Fig. 1), the information and switching bus 4.1.1 (Fig. 1) and the communication channel 6.2 (Fig. . 1) they turn to the subprogram module of the model of innovative development of the enterprise 4.1.3 (Fig. 1), visualizing the graphical interface in accordance with Fig. 1 on the display of the AWP control 1 (Fig. 1). 3.

As before, sequentially manipulating widgets on the graphical interface visualized on the display of the workstation 1 (FIG. 1) in accordance with FIG. 3 and entering information (in the form of digital data) about the innovative development of the enterprise (i.e. updating the data on the goals and objectives of the innovative development of the enterprise / in terms of the impact on the main (production) business processes of the enterprise /, updating the data on the KPI of innovative development enterprises, updating the data on the proposed oil production technology, the development of which is planned as part of the innovative development of the enterprise, updating the KPI data reflecting the target degree of development of the proposed production technology oil, updating the data on the budget planned for development, aimed at achieving a specific KPI of innovative development of the enterprise, etc.), form a specific model of innovative development of the enterprise, which is stored through the subroutine module 4.1.4 (Fig. 1) in the data warehouse. In this case, the following information-switching path is used as a data transmission path for a specific model of enterprise innovative development in a data warehouse: control workstation 1 (Fig. 1), information-switching interacting with a digital data transfer channel 5 (Fig. 1), means interfaces 4.2 (Fig. 1), information and switching bus 4.1.1 (Fig. 1), communication channel 6.3 (Fig. 1) and the sub-program module of data storage 4.1.4 (Fig. 1).

The user also has the opportunity to view on the display AWP control 1 (Fig. 1) of the graphical interface of Fig. 4 "Calculation of the values of the indicator" Additional volumes of marketable oil "" as a result of the subroutine calculation module 4.1.5 (Fig. 1) and software activation of the information and switching communication resource of the form: "communication channel 6.4 (Fig. 1), then information and switching the bus 4.1.1 (Fig. 1), then the interface means 4.2 (Fig. 1) and, finally, the digital data channel 5 (Fig. 1). " The control AWP 1 (Fig. 1) is connected to the last of the above digital channels for information and switching, providing the start of calculating the values of the specified indicators visualized on the display of the AWP control 1 (Fig. 1) in accordance with the executable calculation algorithms.

Also, thanks to the operation of the server 4 (FIG. 1) with the direct participation of the above-mentioned subprogram modules with graphical interfaces presented in FIG. 2 - FIG. 4, the subroutine module for generating knowledge and visualization cards 4.1.6 (Fig. 1) creates on the display the workstation ARM 1 (Fig. 1) a graphical interface corresponding to the image in Fig. 5.

On the graphical interface in accordance with FIG. 5 "a" - FIG. 5 "g" displayed on the control workstation 1 display (Fig. 1), within the KPI widgets "Decision Tree", "Additional Analytics" and "Production Scheme" widgets, the calculation model data is converted into visual images in accordance with the notation that provides type identification visualization object (product / value chain process, type of innovative product, etc.), type of visualization indicator (financial, economic, operational, functional or technical), specification of the type of indicator (primary or estimated), availability Onen in the implementation of innovative programs and the degree of significance of deviation (critical, significant or valid), as well as the causes of deviations.

Data exchange between the control workstation 1 (Fig. 1) and the subroutine module 4.1.6 is carried out according to the information and switching communication resource of the form: "subroutine module for generating knowledge and visualization cards 4.1.6 (Fig. 1), communication channel 6.5 (Fig. 1 ), then the information and switching bus 4.1.1 (Fig. 1), then the interface means 4.2 (Fig. 1), then the digital data transfer channel 5 (Fig. 1) and, finally, the AWP control 1 (Fig. 1) " .

The information arriving in the subprogram module for collecting data on environmental parameters 4.1.7 (Fig. 1), the graphical interface of which is presented in FIG. 6, is sent from the automated data input AWP during monitoring 3 (Fig. 1) to the digital data transfer channel 5 (Fig. 1.), passes through the interface means 4.2 (Fig. 1), and then enters the information-switching bus 4.1. 1 (Fig. 1), and then through a communication channel 6.6 (Fig. 1) is processed on the mentioned subprogram module. It should be noted that the automated data entry workstation in the monitoring process 3 (Fig. 1) has access only to this subroutine module, which queries the data on environmental parameters, updates the data and generates tabular and graphical reporting forms.

The subroutine module of event analytics 4.1.8 (Fig. 1), the graphical interface of which is presented in Fig. 7 interacts with the control workstation 1 (Fig. 1) along the following information-switching circuit: communication channel 6.7 (Fig. 1), information-switching bus 4.1.1 (Fig. 1), interface means 4.2 (Fig. 1), and digital data transmission channel 5 (Fig. 1). The subprogramme module of event analytics 4.1.8 (Fig. 1) makes it possible to investigate and assess the level of superiority over technical counterparts based on consideration of investment and operating cash flows, draw up a risk card and detail operational parameters of oil production using innovation independently from the bottom and from the upper horizons. In addition, by means of widgets on the graphical interface in question in accordance with FIG. 7 "a" - FIG. 7 "c", the possibility of a thorough examination of the impact of risks on the innovation process is realized.

The level of detail of the reports is set by the results of the operation of the subprogram module 4.1.9 (Fig. 1), the capabilities of which are illustrated by images of the graphical interface in accordance with Fig. 8 "a" - FIG. 8 b, and the corresponding report can be presented, depending on the choice of the widget on the graphical interface, not only in a detailed form, but also in a consolidated form. The latter contributes to a significant acceleration of management decisions.

This subroutine module interacts with the control workstation 1 (Fig. 1) along the following information-switching circuit: communication channel 6.8 (Fig. 1), information-switching bus 4.1.1 (Fig. 1), interface means 4.2 (Fig. 1) and digital data channel 5 (Fig. 1).

The sub-program module of scenario planning 4.1.10 (Fig. 1) in the proposed hardware-software complex is intended to calculate the planned values of the indicators of the innovation project relating to scenarios selected for the purpose of analysis. In addition, through this subroutine module (the graphical interface of which is shown in Fig. 9), it is possible to compare predetermined scenarios by indicators selected by the methodologies laid down in the software part of the proposed hardware-software complex. Information-switching interaction with the workstation 1 (Fig. 1) of the subprogram module 4.1.10 (Fig. 1) differs from the interaction described above for the subprogram module 4.1.9 (Fig. 1) only by the communication channel, i.e. instead of the communication channel 6.8 (Fig. 1), the communication channel 6.9 (Fig. 1) is used.

As the name of the subroutine module 4.1.11 (Fig. 1) follows, it is intended for the operational adjustment of the parameters of the enterprise innovative development model. The considered subprogramme module provides updating the parameters of the model of innovative development of an enterprise in the field of oil production in relation to the facility (s) that form the model of innovative development of the enterprise, indicators, relationships between objects (calculation algorithms) and primary indicators. The graphical interface of the subroutine module 4.1.11 (FIG. 1) has the form shown in FIG. 10, wherein the widgets of the graphical interface in accordance with FIG. 10 "a" allows you to specify the form for creating the factor, widgets for the graphical interface in accordance with FIG. 10 b allow you to specify the form of risk creation, and widgets of the graphical interface in accordance with FIG. 10 "in" allow you to issue a decision card.

The information-switching interaction with the workstation 1 (Fig. 1) of the subprogramme module 4.1.11 (Fig. 1) differs from the interaction described above for the subprogramme module 4.1.10 (Fig. 1) only with the communication channel, i.e. instead of the communication channel 6.9 (Fig. 1) for the subroutine module 4.1.11 (Fig. 1), the communication channel 6.10 (Fig. 1) is used.

Thus, the proposed hardware-software complex in terms of oil production allows us to solve a long-overdue task consisting in the ability to control the innovative development of the enterprise, the possibility of which is not available in the prototype device. In addition, due to the use in the claimed hardware and software complex of the original software product that we created and used the previously unknown composition and circuit design of subprogram modules unknown in the prior art, an increase in speed of 2.6-3 times is achieved relative to the prototype device.

Example No. 2

As an illustration of the practical implementation of the proposed hardware and software complex in the field of oil (hydrocarbon) processing, an innovation is used regarding the technology for the production of synthetic oil and oil product components from associated petroleum gas (in particular, using innovative heterogeneous catalysts (see RF invention No. 2482917, IPC : B01J 37/02, publ. 05.27.2013, Bull. No. 15)). After installation on the AWP 1-3 (Fig. 1) and server 4 (Fig. 1) of the above-mentioned software products for the user on the AWP control 1 (Fig. 1), the graphical interface is visualized in accordance with Fig. 11 formed by the subroutine module of the enterprise model 4.1.2 (Fig. 1). This subroutine module is connected to the control workstation 1 (Fig. 1), information and switching interacting with the digital data channel 5 (Fig. 1), through the communication channel 6.1 (Fig. 1) connected to the information and switching bus 4.1.1 ( Fig. 1), which, in turn, is also information-switching through the server interface means 4.2 (Fig. 1) connected to the mentioned digital data channel 5 (Fig. 1).

By sequentially manipulating widgets on the graphical interface visualized on the display of the workstation 1 (FIG. 1) in accordance with FIG. 11 and entering information about the enterprise (i.e. updating the data on the process of the value chain of the enterprise, updating the data on the product of the value chain of the enterprise, etc.), form a specific model of the enterprise, which is saved by transmitting data via the 6.1 communication channel ( Fig. 1), the information and communication bus 4.1.1 (Fig. 1) and the communication channel 6.3 (Fig. 1) through the subroutine module 4.1.4 (Fig. 1) in the data warehouse.

Then, from the control workstation 1 (Fig. 1) via the digital data transmission channel 5 (Fig. 1), through the interface means 4.2 (Fig. 1), the information and switching bus 4.1.1 (Fig. 1) and the communication channel 6.2 (Fig. . 1) they turn to the subprogram module of the model of innovative development of the enterprise 4.1.3 (Fig. 1), visualizing the graphical interface in accordance with Fig. 1 on the display of the AWP control 1 (Fig. 1). 12.

As before, sequentially manipulating widgets on the graphical interface visualized on the display of the workstation 1 (FIG. 1) in accordance with FIG. 12 and entering information (in the form of digital data) on the innovative development of the enterprise (i.e. updating the data on the goals and objectives of the innovative development of the enterprise / in terms of the impact on the main (production) business processes of the enterprise /, updating the data on the KPI of innovative development enterprises, updating the data on the proposed technology of oil refining (including regarding the processing of hydrocarbon in the form of associated petroleum gas), the development of which is planned as part of the innovative development of the enterprise, updating Adjusting the KPI data reflecting the target degree of development of the proposed oil refining technology, updating the data on the budget planned for development, aimed at achieving a specific KPI of innovative development of the enterprise, etc.), form a specific model of innovative development of the enterprise, which is saved through the subprogramme module 4.1 .4 (Fig. 1) in the data warehouse. In this case, the following information-switching path is used as a data transmission path for a specific model of the enterprise’s innovative development in the storage: control workstation 1 (Fig. 1), information-switching interacting with a digital data transfer channel 5 (Fig. 1), a means of interfacing 4.2 (Fig. 1), information-switching bus 4.1.1 (Fig. 1), communication channel 6.3 (Fig. 1) and the sub-program module of data storage 4.1.4 (Fig. 1).

The user also has the opportunity to view on the display AWP control 1 (Fig. 1) of the graphical interface of Fig. 13 indicators for the output of synthetic oil as a result of the work of the subroutine calculation module 4.1.5 (Fig. 1) and software activation of the information and switching communication resource of the form: “communication channel 6.4 (Fig. 1), then the information and switching bus 4.1.1 ( Fig. 1), then the interface means 4.2 (Fig. 1) and, finally, the digital data channel 5 (Fig. 1). " The control AWP 1 (Fig. 1) is connected to the last of the indicated digital channels for information and switching, providing the start of calculating the values of visualized values displayed on the display of the AWP control 1 (Fig. 1) in accordance with the executable calculation algorithms.

Also, thanks to the operation of the server 4 (FIG. 1) with the direct participation of the above-mentioned subprogram modules with graphical interfaces presented in FIG. 11 - FIG. 12, the subroutine module for generating knowledge and visualization cards 4.1.6 (Fig. 1) creates on the display the workstation ARM 1 (Fig. 1) a graphical interface corresponding to the image in Figs. fourteen.

On the graphical interfaces in accordance with FIG. 14 "a" - FIG. 14 "and" displayed on the display of the workstation 1 (Fig. 1), as part of the activation of widgets according to the environment of processes, factor indicators, etc. the data of the calculation model are converted into visual images in accordance with a notation that provides identification of the type of visualization object (product / value chain process, type of innovative product, etc.), the type of visualization indicator (financial, economic, operational, functional or technical), specification of the type of indicator (primary or estimated), the presence of deviations in the implementation of the innovation program and the degree of significance of the deviation (critical, significant or permissible), as well as the reasons for loony.

Data exchange between the control workstation 1 (Fig. 1) and the subroutine module 4.1.6 is carried out according to the information and switching communication resource of the form: "subroutine module for generating knowledge and visualization cards 4.1.6 (Fig. 1), communication channel 6.5 (Fig. 1 ), then the information and switching bus 4.1.1 (Fig. 1), then the interface means 4.2 (Fig. 1), then the digital data transfer channel 5 (Fig. 1) and, finally, the AWP control 1 (Fig. 1) " .

The information arriving in the subprogram module for collecting data on environmental parameters 4.1.7 (Fig. 1), the graphical interface of which is presented in FIG. 15, is sent from the automated workplace of input of actual data during monitoring 3 (Fig. 1) to the digital data transfer channel 5 (Fig. 1.), passes through the interface means 4.2 (Fig. 1), and then enters the information-switching bus 4.1. 1 (Fig. 1), and then through a communication channel 6.6 (Fig. 1) is processed on the mentioned subprogram module. It should be noted that the automated data entry workstation in the monitoring process 3 (Fig. 1) has access only to this subroutine module, which queries the data on environmental parameters, updates the data and generates tabular and graphical reporting forms.

The subroutine module of event analytics 4.1.8 (Fig. 1), the graphical interface of which is presented in Fig. 16 interacts with the workstation 1 (Fig. 1) along the following information-switching circuit: communication channel 6.7 (Fig. 1), information-switching bus 4.1.1 (Fig. 1), interface means 4.2 (Fig. 1) and digital data transmission channel 5 (Fig. 1). The subroutine module of event analytics 4.1.8 (Fig. 1) allows you to draw up a risk card. In addition, by means of widgets on the graphical interface in question in accordance with FIG. 16, the possibility of a detailed review of the impact of the identified risk on the characteristics of the innovation process is realized.

The level of detail of the reports is set by the results of the operation of the subprogram module 4.1.9 (Fig. 1), the capabilities of which are illustrated by images of the graphical interface in accordance with Fig. 17, and the corresponding report can be presented, depending on the choice of the widget on the graphical interface, for example, in a consolidated form. Presentation in a consolidated form contributes to a significant acceleration of management decisions.

This subroutine module interacts with the control workstation 1 (Fig. 1) along the following information-switching circuit: communication channel 6.8 (Fig. 1), information-switching bus 4.1.1 (Fig. 1), interface means 4.2 (Fig. 1) and digital data channel 5 (Fig. 1).

The sub-program scenario planning module 4.1.10 (Fig. 1) in the proposed hardware-software complex allows, in particular, to calculate the performance index of the indicator relating to the volume of synthetic oil output in the context of any implementation scenarios of the innovative project (the graphical interface is shown in Fig. 18). In addition, through this subroutine module, it is possible to compare predetermined scenarios by indicators, the selection of which is carried out according to the methodologies laid down in the software part of the proposed hardware-software complex. Information-switching interaction with the workstation 1 (Fig. 1) of the subprogram module 4.1.10 (Fig. 1) differs from the interaction described above for the subprogram module 4.1.9 (Fig. 1) only by the communication channel with the bus 4.1.1 (Fig. 1), i.e. instead of the communication channel 6.8 (Fig. 1) for the subroutine module 4.1.10 (Fig. 1) use the communication channel 6.9 (Fig. 1).

As the name of the subroutine module 4.1.11 (Fig. 1) follows, it is intended for the operational adjustment of the parameters of the enterprise innovative development model. The latter includes the updating of the parameters of the model of innovative development of the enterprise in the field of hydrocarbon processing in relation to the object (s) that form the model of innovative development of the enterprise, indicators, relationships between objects (calculation algorithms) and the values of primary indicators. The graphical interface of the subroutine module 4.1.11 (FIG. 1) has the form shown in FIG. 19, wherein the widgets of the graphical interface in accordance with FIG. 19 "a" allow you to specify the form for creating the factor, widgets for the graphical interface in accordance with FIG. 19 b allow you to specify the form of risk creation, and widgets of the graphical interface in accordance with FIG. 19 "in" allow you to issue a decision card.

The information-switching interaction with the workstation 1 (Fig. 1) of the subprogramme module 4.1.11 (Fig. 1) differs from the interaction described above for the subprogramme module 4.1.10 (Fig. 1) only with the communication channel, i.e. instead of communication channel 6.9 (Fig. 1), communication channel 6.10 (Fig. 1) is used to communicate with bus 4.1.1 (Fig. 1) of subprogram module 4.1.11 (Fig. 1).

Thus, the proposed hardware and software complex regarding hydrocarbon processing allows us to solve a long-overdue task consisting in managing the innovative development of the enterprise, the possibility of which is not available in the prototype device. In addition, due to the use in the claimed hardware and software complex of the original software product created by us, and the use of previously unknown composition and circuit construction of subprogram modules unknown in the prior art, a speed increase of 2.6-3 times with respect to the prototype device is achieved.

It is obvious and valuable that the subject of the proposed new technical solution is not limited to the graphic materials illustrated above and their accompanying actions (or sequence of actions). In particular, actions to manage the innovative development of an enterprise in the field of oil production and refining can be carried out in a manner different from the above and / or simultaneously with other actions not represented and not described in the embodiments of the claimed proposed hardware-software complex.

Claims (2)

1. Hardware-software complex for managing the innovative development of an enterprise in the field of oil production and refining, characterized by the presence of a server equipped with an input / output connected to a digital data line, with a software module for evaluating the effectiveness and monitoring the implementation of innovative projects for management installed on it innovative development of the enterprise using simulation algorithms, and peripheral AWP management, AWP examination and AWP input data in the process of mon toring, inputs / outputs are also connected to a digital data line, and the said software module is formed from a subprogram module of the enterprise model, the input / output of which is connected to the server information and switching bus, the subprogram module of the enterprise innovative development model, the input / output of which is connected to the information - the switching bus of the server, the sub-program module of the data warehouse, the input / output of which is connected to the information and switching bus of the server, the sub-program module of the calculated a module, the input / output of which is connected to the information and switching bus of the server, a subroutine module for generating knowledge and visualization cards, the input / output of which is connected to the information and switching bus of the server, a subroutine module for collecting data on environmental parameters, the input / output of which is connected to the information - the switching bus of the server, the subroutine module, the input / output of which is connected to the information and switching bus, the subroutine module of the event analytics, the input / output of which is connected to the information on-line switching bus of the server, subroutine module for setting the level of detail of reports, the input / output of which is connected to the information-switching bus of the server, subroutine module for scenario development, the input / output of which is connected to the information-switching bus of the server, and the subroutine module for the operational adjustment of the parameters of the innovative model development of the enterprise, the input / output of which is connected to the information and switching bus of the server. 2. The hardware-software complex according to claim 1, characterized in that the Internet is used as a digital data transmission channel.

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