RU2727530C1 - System for optimization of investment flows - Google Patents

Abstract

FIELD: computer equipment.SUBSTANCE: invention relates to computer engineering. System comprises two control objects, an analysis module of diagnosed parameters, comprising a unit for analysing the diagnosed parameters, a unit for inputting reference diagnostic parameters, wherein the control objects are water disposal systems, diagnostic parameters analysing unit is configured to input actual values of target reliability, quality, energy efficiency of control objects, unit for input of reference diagnosed parameters is configured to input target values of target reliability, quality, energy efficiency of control objects, and system is additionally equipped with control object characteristics input module, module for determination of operating costs of control objects, comprising unit for determination of operating costs of control objects at actual values of target reliability and quality parameters.EFFECT: wider range of technical means.1 cl, 5 dwg

Description

The system relates to the field of wastewater disposal, as well as methods (devices) for optimizing investment flows during the modernization (reconstruction) of wastewater systems.

Known "System and method of optimizing livestock production" (see patent No. 2399289 - Russian Federation: IPC G06F 1/00 (2006.01), Published: 20.09.2010 Bul. No. 26), including a simulator subsystem, made with the ability to receive a set input parameters of animals and generating a predicted characteristic, wherein at least one of the input parameters of animals is designated as variable input parameters, and an enterprise management subsystem configured to generate an optimized value for at least one variable input parameter based on, at least one criterion for optimization and composition of the animal feed. The use of a group of inventions will increase the productivity of livestock production.

The disadvantage of the known system is its limited scope due to the impossibility of optimizing the costs of modernizing the control object, since the specified system and method take into account only the input and output parameters of the control object (which are variables) and do not take into account the costs of modernization and the cost of maintaining the control object.

The closest analogue to the claimed utility model is the energy consumption control system during the operation of sewage pumping stations (SPS), (see utility model patent No. 94291, Russian Federation: IPC F04B 51/00 (2006.01) / FV Karmazinov, Kinebas A.K., Trukhin Yu.A. et al .; publ. 20.05.2010), including:

a water pumping module containing at least two pumps with suction and discharge pipelines,

a module for analyzing diagnosed parameters, containing a unit for comparing feeds, a unit for correcting a diagnosed parameter by shaft rotation frequency, a unit for correcting a diagnosed parameter by a diameter of an impeller, a unit for analyzing diagnosed parameters, a unit for entering reference diagnosed parameters, while the output of the unit for comparing feeds is connected to the input of the correction unit of the diagnosed parameter by the shaft rotation frequency, the input of the correction block for the diagnosed parameter by the impeller diameter is connected to the output of the correction block of the diagnosed parameter by the shaft rotation frequency, and the outputs of the correction blocks of the diagnosed parameter by the impeller diameter and input of the reference diagnosed parameters are connected to the input of the diagnostic parameter analysis block ;

an instrumentation module containing at least two pump flow sensors, at least two pressure sensors installed respectively on the suction and discharge pipelines, a pump shaft speed sensor, a power consumption meter, with all sensors and a consumption meter the power of the instrumentation module is made mobile and additionally equipped with data recording devices and communication channels, the outputs of data recording devices of at least two pressure sensors, a pump shaft speed sensor and a power consumption meter are connected to the input of the correction unit of the diagnosed parameter on the shaft rotation frequency, and the outputs of the data recording devices of at least two pump flow sensors - to the input of the flow comparison unit,

an energy consumption optimization module containing a unit for forming the hydraulic characteristics of networks, to the input of which, using communication channels, the outputs of data recording devices of at least two pressure sensors and the output of a flow comparison unit, an energy consumption analysis unit, an input unit for diagnosed parameters of competing pumps, a unit analysis of energy consumption of competing pumps, while the outputs of the unit for analyzing the diagnosed parameters and the unit for generating the hydraulic characteristics of networks are connected to the input of the unit for analyzing energy consumption, the outputs of the unit for forming the hydraulic characteristics of networks and the unit for entering diagnosed parameters of competing pumps are connected to the input of the unit for analyzing the energy consumption of the pumps of competitors.

In addition, the energy consumption analysis unit, the energy consumption analysis unit of competing pumps are configured to determine the total energy consumption, the water pumping module is equipped with a receiving tank with a supply pipeline, the instrumentation module is equipped with a rain intensity sensor with a data recording device and a communication channel, and an energy consumption optimization module is a block for inputting the volume of a receiving tank, a block for analyzing a water inflow, a block for inputting the characteristics of a sewage pool, while the suction and pressure pipelines of at least two pumps are connected to the receiving tank, the outputs of the flow comparison unit, a block for entering the volume of a receiving tank, a block for entering the characteristics of a sewage pool and the device for recording data from the rain rate sensor using a communication channel are connected to the input of the water inflow analysis unit, and the output of the water inflow analysis unit is connected to the input of the energy consumption analysis unit and to the input of the energy consumption analysis unit at competitor pumps.

This system is characterized by a limited area of application, because it is designed to solve the optimization problem only on one element of the wastewater disposal system - a sewage pumping station (SPS), and is aimed at reducing only one type of costs - payment for electricity consumption. For this reason, using this system, it is not possible to solve the problem of optimizing investments for the modernization of wastewater systems as a whole, since:

1. It does not take into account:

costs of upgrading elements of management facilities, such as drainage networks, treatment facilities and wastewater outlets;

expenses for the elimination of accidents, the number of which depends on the failure rate of equipment of control objects;

costs of payments for negative impact on the environment, depending on the amount of pollution discharged by the management object into water bodies;

the cost of paying for electricity, wastewater treatment.

2. With its application, it is possible to solve only the problem of optimal selection of pumps from the list of competing pumps within one element (SPS) of the control object, and the problem of substantiating the optimal sequence of modernization cannot be solved.

The object of the present invention is to expand the field of application of the known system.

The problem is solved in such a way that in the known system, which includes at least two control objects, a module for analyzing diagnosed parameters containing a unit for analyzing diagnosed parameters, an input unit for reference diagnosed parameters, in accordance with the present invention:

drainage systems are taken as control objects,

the unit for analyzing the diagnosed parameters is configured to enter the actual values of the target indicators of reliability, quality, energy efficiency of control objects,

the unit for inputting reference diagnosed parameters is configured to input the planned values of the target indicators of reliability, quality, energy efficiency of control objects.

In addition, the system is additionally equipped with:

the module for entering the characteristics of the control object,

a module for determining the operating costs of control objects containing a block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects and a block for determining the operating costs of control objects at the planned values of the target indicators of reliability, quality, energy efficiency of control objects,

a module for determining the costs of carrying out measures to modernize management facilities,

the module for determining the profitability ratio of measures to modernize management facilities,

a module for optimizing investment costs for management objects.

Wherein,

the output of the module for inputting the characteristics of the control object is connected to the input of the unit for analyzing the diagnosed parameters and to the input of the unit for entering the reference diagnosed parameters,

the output of the block for analyzing the diagnosed parameters is connected to the input of the block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects,

the output of the unit for inputting reference diagnosed parameters is connected to the input of the unit for determining operating costs at the planned values of the target indicators of reliability, quality, energy efficiency of control objects,

the output of the unit for analyzing the diagnosed parameters and the output of the unit for inputting the reference diagnosed parameters of control objects is connected to the input of the module for determining the operating costs of control objects and to the input of the module for determining the costs of carrying out measures to modernize control objects,

the output of the module for determining the operating costs of control objects and the output of the module for determining the costs of measures to modernize control objects are connected to the input of the module for determining the profitability ratio of measures to modernize control objects,

the output of the module for determining the profitability ratio of measures to modernize control objects is connected to the input of the module for optimizing investment costs for control objects.

Distinctive features of the claimed system for optimizing investment flows are:

1. Choice of sewerage systems as control objects;

2. Execution of the block for analyzing the diagnosed parameters with the ability to enter the actual values of the target indicators of reliability, quality, energy efficiency of control objects;

3. Execution of the block of input of reference diagnosed parameters with the ability to enter the planned values of the target indicators of reliability, quality, energy efficiency of control objects;

4. Additional supply with the module for entering the characteristics of the controlled object;

5. Additional supply with a module for determining the operating costs of control objects;

6. Inclusion in the module for determining the operating costs of control objects of the block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects;

7. Inclusion in the module for determining the operating costs of control objects of the block for determining operating costs at the planned values of the target indicators of reliability, quality, energy efficiency of control objects;

8. Additional supply with a module for determining the costs of measures to modernize management facilities;

9. Additional supply with a module for determining the profitability ratio of measures to modernize management facilities;

10. Additional supply with a module for optimizing investment costs for management objects.

11. Connection of the output of the control object characteristics input module with the input of the diagnosed parameters analysis unit and with the input of the diagnostic reference parameters input block;

12. Connection of the output of the block for analyzing the diagnosed parameters with the input of the block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects;

13. Connection of the output of the block of input of reference diagnosed parameters with the input of the block for determining the operating costs at the planned values of the target indicators of reliability, quality, energy efficiency of control objects;

14. Connection of the output of the unit for analyzing diagnosed parameters and the output of the unit for inputting reference diagnosed parameters of control objects with the input of the module for determining the operating costs of control objects and with the input of the module for determining the costs of measures to modernize control objects;

15. Connection of the output of the module for determining the operating costs of control objects and the output of the module for determining the costs of measures to modernize control objects with the input of the module for determining the profitability ratio of measures to modernize control objects;

16. Connecting the output of the module for determining the profitability ratio of measures to modernize control objects with the input of the module for optimizing investment costs for control objects.

According to the information available to the authors, the distinctive feature No. 1 is known in the technical literature, and the rest are not, which meets the “novelty” condition of patentability.

The combined use of these distinctive features in the claimed device allows obtaining a positive effect, which consists in the fact that the scope of application of the system expands, since it can be used to solve the problems of optimizing investment flows for the modernization of wastewater systems as a whole. This is achieved due to the presence of distinctive features No. 1-16, because:

- due to the use of distinctive features No. 1, 4, 8, 11, 14, it becomes possible to determine the costs of upgrading elements of management facilities, such as drainage networks, treatment facilities and wastewater outlets;

- due to the use of distinctive features No. 1-7, 11-13, it becomes possible to determine the costs of eliminating accidents, the number of which depends on the failure rate of equipment of control objects;

- due to the use of distinctive features No. 1-7, 11-13, it becomes possible to determine the costs of payments for negative impact on the environment, depending on the amount of pollution discharged by the management object into water bodies;

- due to the use of distinctive features No. 1-7, 11-13, it becomes possible to determine the cost of paying for electricity, for wastewater treatment.

- due to the use of distinctive features No. 9, 10, 15, 16, it becomes possible to substantiate the optimal variant of the sequence of modernization of control objects.

The system proposed by the authors differs from the prototype structurally.

FIG. 1 shows a diagram of the proposed "System for optimizing investment flows", FIG. 2. - an example of a summary table of costs accounted for in the proposed system, in FIG. 3. - an example of a graph with the results of determining the values of the net present value determined in the module for determining the profitability ratio of carrying out modernization measures for each control object, in Fig. 4. - an example of determining the values of the net present value for a group of control objects depending on the order of modernization, FIG. 5 - an example of the optimal sequence of modernization of control objects.

The system contains (see Fig. 1) a module 1 for inputting the characteristics of the control object, into which information is entered on n control objects, with n≥2, the output of which is connected via communication channel 2 to the input of the module 3 for analyzing the diagnosed parameters, containing:

unit 4 for analyzing diagnosed parameters, the output of which is connected via communication channel 5 to the input of unit 6 for determining the operating costs of control objects at actual values of the target indicators of reliability, quality, energy efficiency of control objects and via communication channel 7 to the input of module 8 for determining the costs of carrying out measures for modernization of management facilities,

block 9 for inputting reference diagnosed parameters, the output of which is connected via communication channel 10 to the input of block 11 for determining operating costs of control objects at planned values of target indicators of reliability, quality, energy efficiency of control objects and communication channel 12 to the input of module 8 for determining costs for carrying out measures modernization of management facilities.

Block 6 for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects and block 11 for determining the operating costs of control objects at the planned values of the target indicators of reliability, quality, energy efficiency of control objects constitute module 13 for determining the operating costs of control objects.

The output of the module 8 for determining the costs of measures to modernize control objects via communication channel 14 and the output of the module 13 for determining the operating costs of control objects via communication channel 15 are connected to the input of the module 16 for determining the profitability factor of measures to modernize control objects.

The output of the module 16 for determining the profitability ratio of measures to modernize control facilities via the communication channel 17 is connected to the input of the module 18 for optimizing investment costs for control facilities.

The present invention allows various versions of communication channels 2, 5, 7, 10, 12, 14, 15, 17. For example, on magnetic media, over the Internet, etc.

The proposed System for optimizing investment flows works as follows.

The module 1 is input characteristics of the control object are entered at least the following characteristics of the control object: length L _i and the diameters D _{i i-th} areas of drainage networks, the estimated costs Q _pacch treatment facilities receiver category effluent Ave _NE, the cost per repair C _i section of drainage networks.

From the module 1 for inputting the characteristics of the control object via the communication channel 2, the characteristics of the control object are transmitted to the module 3 for analyzing the diagnosed parameters. They are simultaneously transmitted to the unit 4 for analyzing the diagnosed parameters and the unit 9 for entering the reference diagnosed parameters.

At the same time, the actual target indicators of reliability, quality, energy efficiency of the control object are additionally entered into the block 4 for analyzing the diagnosed parameters of the module 3 for analyzing the diagnosed parameters, and in the block 9 for entering the reference diagnosed parameters of the module 3 for analyzing the diagnosed parameters - the planned target indicators of reliability, quality, energy efficiency of the control object. The actual and planned target indicators of reliability, quality, energy efficiency of the control object in accordance with the present invention include:

1/км;- the specific number of accidents and blockages per the length of the sewer network per year

1 / km;

%;- the share of wastewater not undergoing treatment in the total volume of wastewater discharged into centralized general-purpose or domestic drainage systems

%;

%;- the share of surface wastewater that is not subjected to treatment in the total volume of surface wastewater received in the centralized storm water disposal system

%;

и централизованной ливневой систем водоотведения (в процентах)

%;- the proportion of wastewater samples that do not meet the established standards of permissible discharges, limits for discharges, calculated for the types of centralized drainage systems separately for centralized general-purpose (household)

and centralized storm drainage systems (percentage)

%;

%;- the share of surface wastewater that is not treated, in the total volume of surface wastewater that entered the separate rainwater drainage system

%;

%;- the share of surface wastewater samples that do not meet the established standards for permissible discharges, limits for discharges calculated for a separate rain system

%;

- specific consumption of electrical energy consumed in the technological process of wastewater treatment, per unit volume of treated wastewater, kWh / m ³

- specific consumption of electrical energy consumed in the technological process of wastewater transportation, per unit volume of transported wastewater, kWh / m ³

- specific consumption of electrical energy consumed in the technological process of surface wastewater treatment, per unit volume of treated surface wastewater, kWh / m ³

- specific consumption of electrical energy consumed in the technological process of transporting surface wastewater, per unit volume of transported surface wastewater, kWh / m ³

From the output of the block 4 for analyzing the diagnosed parameters of the module 3 for analyzing the diagnosed parameters via the communication channel 5 to the input of the block 6 for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of the control objects of the module 13 for determining the operating costs of the control object, the characteristics of the control object are transmitted and actual target indicators of reliability, quality, energy efficiency of the controlled object.

From the output of block 9 for inputting reference diagnosed parameters of module 3 for analyzing diagnosed parameters via communication channel 10 to the input of block 11 for determining the operating costs of control objects at planned values of the target indicators of reliability, quality, energy efficiency of control objects of module 13 for determining operating costs of the control object, the characteristics of the control object are transmitted and planned target indicators of reliability, quality, energy efficiency of water disposal systems of the controlled object.

In block 6 for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of the control objects of module 13 for determining the operating costs of the control object, the operating costs of the control object are determined before the modernization measures are taken for each of the n control objects according to the formula

In block 11 for determining the operating costs of the control objects at the planned values of the target indicators of reliability, quality, energy efficiency of the control objects of the module 13 for determining the operating costs of the control object, the operating costs of the control object are determined after carrying out modernization measures for each of the n control objects according to the formula

- затраты на ликвидацию аварий до и после проведения модернизации объекта управления, руб.

Where

- expenses for the elimination of accidents before and after the modernization of the control facility, rubles.

- экологические выплаты до и после проведения модернизации объекта управления, руб.

- environmental payments before and after the modernization of the management facility, rubles.

- затраты электрической энергии на транспортировку и очистку сточных вод, руб.

- the cost of electricity for the transportation and treatment of wastewater, rubles.

By way of example, in FIG. 2, columns 2 and 3 show the results of the estimation of such costs.

From the output of the module 13 for determining the operating costs of the control object through the communication channel 15 to the input of the module 16 for determining the profitability factor of measures to modernize the control object, the obtained values of operating costs are transmitted before and after the modernization of the control object.

From the output of the block 4 of the analysis of the diagnosed parameters of the module 3 of the analysis of the diagnosed parameters, the actual target indicators of reliability, quality, energy efficiency of wastewater disposal systems through the communication channel 7 to the input of the module 8 for determining the costs of measures to modernize the control object, the characteristics of the control object and the actual target reliability indicators are transmitted , quality, energy efficiency of water disposal systems of the controlled object.

From the output of block 9 for inputting reference diagnosed parameters of module 3 for analyzing diagnosed parameters via communication channel 12 to the input of module 8 for determining the costs of modernizing the control object, the characteristics of the control object and the planned target indicators of reliability, quality, energy efficiency of wastewater disposal systems of the control object are transmitted.

In module 8 of determining the costs of carrying out measures to modernize the control object, the volume of costs I for carrying out modernization measures is determined. The present invention allows various methods for determining costs, for example, by estimated cost or by aggregated indicators.

By way of example, in FIG. 2, column 4 shows the results of assessing the cost of measures to modernize the management object.

The volume of costs I from the output of the module 8 for determining the costs of measures to modernize the control object via the communication channel 15 are transmitted to the input of the module 16 for determining the profitability factor of measures to modernize the control object.

In module 16 for determining the profitability ratio of measures to modernize the control object, the net present value (NPV) is determined according to the formula

Hence

where T is the period for assessing the net present value;

k _I - inflation rate, while k _I = const;

k _d - discount factor, while k _d = const;

t - year of assessment from t = 0 to t = T.

Due to the fact that k _I = const and k _d = const are the same for all considered objects, the NPV value depends on the cost of modernization measures and operating costs for each of the n control objects before and after modernization, the determining factor in choosing the optimal sequence of modernization of the control object is profitability ratio of measures to modernize the control object Re

FIG. 3, as an example, a graph is shown with the results of determining the values of the net present value determined in the module for determining the profitability ratio of carrying out modernization measures for each control object. The NPV values for each of the n items shown in FIG. 2 for the evaluation period: 1 - object with Re = 10.20; 2 - the same, Re = 11.10; 3 - the same, Re = 12.26; 4 - the same, Re = 13.28; 5 - the same, Re = 17.28; 6 - the same, Re = 18.64; 7 - the same, Re = 21.06; 8 - the same, Re = 21.95; 9 - the same, Re = 23.72; 10 - the same, Re = 31.82.

Additionally, in FIG. 4 shows the results of summing up the values of the net present value for a group of n objects, depending on the order of their modernization. NPV values for a group of objects: line 1 - modernization of all objects, beginning in the first year of the evaluation period; line 2 - modernization of facilities one by one within 10 years, modernization of the facility with a lower profitability factor of the non-modernized ones; line 3 - modernization of facilities alternately for 10 years, arbitrary choice of the facility for modernization; line 4 - modernization of facilities one by one within 10 years, modernization of the facility with a lower cost of modernization from not modernized; line 5 - modernization of facilities one by one for 10 years, modernization of the facility with a high profitability factor from not modernized.

Estimating the values of the net present value of the management objects from FIG. 4 it is determined that for the presented example, the most effective sequence is the modernization of the control object with a lower profitability factor of the measures to modernize the control object from the non-modernized ones, represented by line 2.

From the output of the module 16 for determining the profitability factor of measures to modernize the control objects via the communication channel 17 to the input of the module 18 for optimizing investment costs for the control objects, the values of the profitability factor of the measures to modernize the control object are transmitted.

In module 18, optimization of investment costs by management objects, the profitability ratio of measures to modernize the management object is ranked from lower to higher. By way of example, in FIG. 5 shows the result of this stage of determining the optimal sequence of modernization of control objects according to the example under consideration.

Thus, the proposed system is characterized by "industrial applicability".

Claims (17)

A system for optimizing investment flows, containing at least two control objects, a module for analyzing diagnosed parameters containing a unit for analyzing diagnosed parameters, an input unit for reference diagnosed parameters, characterized in that drainage systems are taken as control objects, the unit for analyzing the diagnosed parameters is configured to enter the actual values of the target indicators of reliability, quality, energy efficiency of control objects, the block for inputting reference diagnosed parameters is configured to input the planned values of the target indicators of reliability, quality, energy efficiency of control objects, and the system is additionally equipped the module for entering the characteristics of the control object, a module for determining the operating costs of control objects containing a block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects and a block for determining the operating costs of control objects at the planned values of the target indicators of reliability, quality, energy efficiency of control objects, a module for determining the costs of carrying out measures to modernize management facilities, the module for determining the profitability ratio of measures to modernize management facilities, a module for optimizing investment costs for management objects, wherein the output of the module for inputting the characteristics of the control object is connected to the input of the unit for analyzing the diagnosed parameters and to the input of the unit for entering the reference diagnosed parameters, the output of the block for analyzing the diagnosed parameters is connected to the input of the block for determining the operating costs of control objects at the actual values of the target indicators of reliability, quality, energy efficiency of control objects, the output of the unit for inputting reference diagnosed parameters is connected to the input of the unit for determining operating costs at the planned values of the target indicators of reliability, quality, energy efficiency of control objects, the output of the unit for analyzing the diagnosed parameters and the output of the unit for inputting the reference diagnosed parameters of control objects is connected to the input of the module for determining the operating costs of control objects and to the input of the module for determining the costs of carrying out measures to modernize control objects, the output of the module for determining the operating costs of control objects and the output of the module for determining the costs of measures to modernize control objects are connected to the input of the module for determining the profitability ratio of measures to modernize control objects, the output of the module for determining the profitability ratio of measures to modernize control objects is connected to the input of the module for optimizing investment costs for control objects.

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