RU2452003C2 - System for optimising settling time of oil products in storage reservoirs depending on temperature distribution of oil product on height of reservoir - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: system for optimising settling time of oil products in storage reservoirs depending on the temperature distribution of the oil product on the height of the reservoir has a module for identifying the base address of the section of the oil product, a module for identifying the base address of the page of the reservoir, a module for generating signals for reading parameters of an area of the reservoir, a module for recording parameters of the area of the reservoir, a module for generating signals for calling a subprogram for calculating the settling rate of particles of an oil product pollutant, a module for recording the settling rate of particles of the oil product pollutant, a module for selecting the average settling rate of particles of the oil product pollutant on the area of the reservoir, a module for comparing the average settling rate of particles of the oil product pollutant on the area of the reservoir with a standard settling rate, a module for identifying the base address of the height of the area of the reservoir, a module for generating signals for reading the average calculated-allowable settling time of the oil product on the area of the reservoir, a module for outputting the calculated-allowable settling time of the oil product.

EFFECT: faster operation of the system by excluding data search in the entire server database and localising search only in base addresses of databases.

13 dwg

Description

The invention relates to computer technology, in particular to a system for optimizing the time of settling of oil products in storage tanks, depending on the distribution of the temperature of the oil product over the height of the tank, which implements the use of new information technologies in the storage of oil products.

One of the ways to clean fuel from mechanical impurities is sedimentation. Preliminary sedimentation of the fuel allows to reduce a significant amount of mechanical impurities and water droplets even before filtering the fuel. The effectiveness of the sedimentation depends both on its duration and on the viscosity and density of the fuel, on the nature of the material of the pollution particles, their mass and size. The higher the viscosity and density of the fuel, the slower the precipitation of particles of mechanical impurities and water droplets and, therefore, the longer it takes to settle the fuel.

The standard for settling fuel in tanks of fuel and lubricants services is established by order of the Air Transport Department of the Ministry of Transport of the RSFSR No. DV-126 of 10/17/1992 and is 4 hours per 1 meter of level. The sedimentation rate of particles of mechanical impurities in the range of ~ 0.07 mm / s corresponds to this standard. However, this norm does not take into account not only the density of the material of the particles of pollution and their sizes, but also the density, viscosity and temperature of the fuel itself.

In [3], a theoretically substantiated result of the study of the processes of sedimentation of fuel in tanks is given. This result shows that the sedimentation rate V ₀ of pollution particles in aviation fuel

depends on the radius r ₃ of the pollution particles, the density ρ ₃ of the pollution particles, the density ρ _T and the viscosity γ _{T of the} fuel.

In turn, both the fuel density ρ _T and the fuel viscosity γ _T are functions of the temperature t of the fuel:

where t is the current temperature of the fuel, ρ ₂₀ is the density of the fuel at a temperature of + 20 ° C, indicated in the passport for fuel (t = + 20 ° C is the temperature of standard atmospheric conditions for aviation fuel).

Since formulas (1) - (3) are valid both for motor fuels related to light petroleum products and for special purpose liquid petroleum oils [4], we will build all further considerations for petroleum products.

Given this, the establishment of the estimated allowable time of settling of the oil product for each reservoir of fuel and lubricants service can be determined only by considering the characteristics of the distribution of temperature of the oil product over the height of each individual tank.

For this, the graph of the distribution of oil temperature over the height of the tank is divided into separate sections. As the end (boundary) points of the sections, the points of the graph are considered at which the temperature of the oil product is measured by a special system for monitoring the parameters of the oil product along the height of the tank.

Each section of the obtained graph partition is characterized by temperature values at its boundaries. In this case, the temperature of the lower boundary of one section is equal to the temperature of the upper boundary of the lower section adjacent to it.

Dividing the tank into sections allows you to more closely monitor changes in the sedimentation rate of particles of contamination of the oil product, and, therefore, to more accurately determine the estimated allowable time of settling.

For this, according to formulas (1) - (3), the sedimentation rate of pollution particles is determined for each boundary temperature of the selected section of the reservoir. Interpreting further the sedimentation particle sedimentation rate obtained for the temperature of the upper boundary of the reservoir section, as the entry velocity to the reservoir section, and the sedimentation particle sedimentation rate obtained for the lower boundary temperature of the reservoir section, as the exit velocity from the reservoir section, the average sedimentation particle velocity at this section of the tank. From here, knowing the height of the reservoir section, it is possible to determine the estimated allowable settling time of the oil product as the ratio of the section height to the average sedimentation rate of the pollution particles in this section.

The total set of obtained average time intervals for all sections of the reservoir will determine the estimated allowable time of sedimentation of the oil product in the reservoir.

In this regard, it seems advisable to create such an automated system that would allow identifying the readiness of the oil product in storage tanks for issuing the average sedimentation rate of pollution particles in each section of the tank with the calculation of the allowable settling time of the oil product, both average over the sections of the tank and the total reservoir.

Known systems that could be used to solve the problem [1, 2].

The first of the known systems comprises data reception and storage units connected to control and data processing units, search and selection units connected to data storage and display units, the synchronizing inputs of which are connected to the outputs of the control unit [1].

A significant drawback of this system is the impossibility of solving the problem of updating data stored in memory in the form of relevant documents, simultaneously with solving the problem of delivering the contents of these documents to users in real time.

Another system is known, containing a central processor module, the inputs of which are connected to the memory modules and to the data preparation and input modules, and the outputs are connected to the corresponding memory modules, the data processing module, the information inputs of which are connected to the outputs of the corresponding memory modules, the synchronizing inputs are connected to control outputs of the central processor module, and the output of the module is the information output of the system [2].

The last of the above technical solutions is closest to the described.

Its disadvantage lies in the low speed of the system, due to the fact that the implementation of analytical data processing procedures is carried out by searching the entire database, which, when the database is large, inevitably leads to unreasonably large time spent on obtaining analytical estimates.

The purpose of the invention is to increase the system performance by excluding data search over the entire volume of the server database and localizing the search only at the base addresses of the database, the corresponding identifiers of the oil product and its reservoirs, as well as the identifiers of sections of a separate reservoir and the length of each of them.

This goal is achieved by the fact that in the system containing the identification module of the base address of the oil product section, the information input of which is the first information input of the system, designed to receive the request codogram from the workstation of the system user, the synchronizing input of the identification module of the base address of the oil product section is the first synchronizing input a system designed to receive synchronization signals of entering a request codogram from an automated of the workplace of the system user to the identification module for the base address of the oil product partition, the first information output of the module for identifying the base address of the oil product is the first information output of the system designed to issue codes of standard density of the oil product, density and radius of particles of oil pollution to the first information input of the database server, module for generating signals for reading parameters of a reservoir section, one information input of which is connected to volt To the information output of the module for identifying the base address of the oil product section, one information output of the module for generating signals for reading the parameters of the tank section is the first address output of the system designed to provide the address of the section of the tank for the address input of the database server, and the synchronizing output of the module for generating signals for reading the parameters of the tank section is the first synchronizing system output intended for issuing control signals for reading parameter in the tank section, to the input of the first channel channel interrupt channel, the module for registering the parameters of the tank section, the information input of which is the second information input of the system, designed to receive codes of the parameters of the tank section read from the server database, the synchronizing input of the module for registering the parameters of the tank section is the second system synchronizing input, intended for receiving the signals of entering the codes of the parameters of the tank section, read from the server database a, in the module for registering the parameters of the reservoir section, the module for registering the sedimentation rate of particles of oil pollution, the information input of which is the third information input of the system designed to receive codes for the sedimentation rate of particles of oil pollution read from the server database, which synchronizes the input of the module for registering the sedimentation rate of particles of oil pollution oil product is the third synchronizing input of the system, designed to receive signals for entering sedimentation rate codes I of oil pollution particles, read from the server database, into the module for registering the sedimentation rate of oil pollution particles, a module for generating signals to read the average acceptable oil sedimentation time over a portion of the tank, the information output of which is the second address output of the system designed to provide the average address section of the reservoir of the estimated allowable time of sedimentation of the oil product to the address input of the database server, and the synchronizing output of the module f of the readout signals of the average of the estimated allowable settling time of the oil product over the portion of the tank is the second synchronizing output of the system, designed to issue control signals for reading the average of the calculated portion of the allowable settling time of the oil product at the input of the first interrupt channel channel of the database server, the module for recording the average over the portion of the reservoir the estimated allowable settling time of the oil product, the information input of which is the fourth information an ionic input of the system, designed to receive codes of the average for the portion of the tank estimated settlement time of the oil product read from the server database, the synchronization input module of the average of the section of the reservoir of the estimated settlement time of oil is the fourth synchronizing input of the system, designed to receive signals codes of the average calculated over the allowable settling time of the oil product over the tank section, read from the server database, in the registration bar of the average calculated permissible settling time of the petroleum product over the tank section, the module for issuing the estimated permissible settling time of the petroleum product, the first information input of which is connected to another information output of the module for generating the signal readings of the reservoir section parameters, the second information input of the module for issuing the estimated permissible settling time of the petroleum product connected to the third information output of the identification module of the base address of the oil product section, and a third The fourth and fourth information inputs of the module for calculating the estimated allowable settling time of the oil product are connected to the first and second information outputs of the module for registering the average for the section of the tank, the average settlement time of the oil product, respectively, the synchronizing input of the module for issuing the estimated allowable time for settling the oil is connected to the synchronizing output of the registration module average over the estimated portion of the reservoir acceptable oil settling time, one information This output of the module for issuing the estimated allowable time for settling the oil product is the second information output of the system, intended for issuing codes of the average for the portion of the tank for settling the oil product at the automated workstation of the user of the system, the other information output for the module for issuing the estimated allowable time for settling the oil is the third information output of the system intended for issuing a code of the estimated allowable settling time for oil of the product to the automated workstation of the user of the system, one synchronizing output of the module for issuing the estimated allowable settling time of the oil product is connected to the counting input of the module for generating signals for reading the parameters of the tank section, with the first installation input of the module for registering parameters of the tank section, with the first installation input of the module for generating the signals for reading the average in the area of the reservoir of the estimated allowable time of sedimentation of the oil product, with the first installation input of the module registration of the average calculated-permissible settling time of the oil product over a portion of the tank, and it is the first signal output of the system intended for issuing an identification signal of the average calculated-permissible settling time of a petroleum product over a section of the tank at the user's computer workstation, another synchronizing output of the calculation-permissible dispensing module the time of sedimentation of the oil product is connected to the second installation input of the module for generating read signals of medium on the reservoir section of the estimated permissible settling time of the oil product, with the second installation input of the module for registering the average calculation of the permissible settling time of the oil product in the reservoir section, with the second installation input of the module for registering the reservoir section parameters, with one installation input of the module for identifying the base address of the oil product section, with one installation input of the module for generating signals for reading the parameters of the reservoir section and at the same time is the second signal output of the system We are designed to issue an identification signal for the estimated allowable time of settling of the oil product at the user's computer workstation, characterized in that it includes an identification module for the base address of the tank page, the first and second information inputs of which are connected to the fourth and fifth information outputs of the base identification module the addresses of the oil product section, respectively, and the synchronizing input of the identification module of the base address of the tank page is connected to the output of the identification module of the base page address of the reservoir page is connected to another information input of the module for generating the signals for reading the parameters of the tank section, and the synchronizing output of the module for identifying the base address of the tank page is connected to the clock input of the module for generating signals for reading the parameters of the tank section , a module for generating call signals of a subroutine for calculating speed sedimentation of oil pollution particles, the first, second and third information inputs of which are connected to the first, second and third information outputs of the module for recording the parameters of the tank section, respectively, one clock input of the signal generation module for generating call signals of the subroutine for calculating the sedimentation rate of oil particles is connected to the synchronization output of the parameter registration module section of the tank, information output of the module for generating signal signals of the calculation routine the sedimentation rate of oil pollution particles is the fourth information output of the system, intended for issuing the temperature code of the reservoir section to the second information input of the database server, and the synchronizing output of the call signal generation module of the subroutine for calculating the sedimentation rate of oil pollution particles is the third synchronizing output of the system, intended for issuing signals call control routines for calculating the sedimentation rate of particles of oil pollution input to the input of the second channel for interrupting the database server, the selection module for the average sedimentation rate of the oil product particles, the first information input of which is connected to the first information output of the module for registering the parameters of the reservoir, and the second and third information inputs of the selection module for the average of the reservoir speed sedimentation particles of oil pollution are connected to the first and second information outputs of the module for registering sedimentation particles pollution rate respectively, the synchronizing input of the selection module of the average sedimentation rate of the oil product particles sedimentation rate is connected to the synchronizing output of the module for registering the sedimentation rate of the oil product particles, and the first and second installation inputs of the selection module of the selection of the average sedimentation rate of the oil product particles are connected to one and the other the synchronizing outputs of the module for issuing the estimated allowable settling time of the oil product, respectively, the information output of the selection module of the average sedimentation rate of the oil product particles sedimentation particles is connected to one information input of the module for generating the signals of reading the average of the calculated average allowable sedimentation time of the oil product, one synchronizing output of the selection module of the selection of the average average sedimentation rate of the oil product particles sedimentation particle is connected to another synchronizing input of the signal generating module of the call subroutine of the calculation of the sedimentation rate particles of oil pollution and with one installation input of the module for registering the sedimentation rate of particles of oil pollution, the other synchronizing output of the selection module of the average sedimentation rate of particles of oil pollution in the reservoir section is connected to the installation input of the signal generation module of the subroutine for calculating the sedimentation rate of the particles of oil pollution and with another installation input module for registering the sedimentation rate of particles of oil pollution, the average comparison module in the section of the reservoir of the sedimentation rate of oil pollution particles with a standard sedimentation rate, the first information input of which is connected to the information output of the selection module of the average sedimentation rate of particles of oil pollution in the reservoir section, the second information input of the module for comparing the average sedimentation rate of particles of oil pollution in the reservoir of the normative rate subsidence is connected to another information output of the module for generating signals for reading parameters tank asta, and the third and fourth information inputs of the module for comparing the average sedimentation rate of the oil product particle sedimentation rate with the standard sedimentation rate are connected to the third and sixth information outputs of the module for identifying the base address of the oil product section, respectively, the synchronizing input of the module for comparing the average particle sedimentation rate of the tank section oil product pollution with a standard sedimentation rate is connected to another synchronizing output of the village module the average of the sedimentation rate of the oil product pollution particles, the first synchronizing output of the module for comparing the average of the sedimentation rate of the oil pollution particles with the standard sedimentation rate is connected to another installation input of the module for generating readings of the parameters of the tank section, with the third installation input of the readout signal generation module the average over the portion of the reservoir of the estimated permissible settling time of the oil product, with the third by the input of the module for registering the average calculated-permissible settling time of the oil product over the tank section, with the third installation input of the module for selecting the average sedimentation rate of the oil product particles over the tank section, with the third installation input of the module for registering the tank section parameters, with the other installation input of the section base address identification module and at the same time it is the third signal output of the system, intended for delivery to an automated workstation the user of the oil product unavailability system for output, the second synchronizing output of the module for comparing the average sedimentation rate of the oil product particles with the standard sedimentation rate is the fourth signal output of the system designed to provide the user with an oil product readiness system for output, and the identification module the base address of the height of the section of the tank, the information input of which is connected to the fourth information the output of the module for registering the parameters of the tank section, and the first and second synchronizing inputs of the module for identifying the base address of the height of the tank section are connected to the second and third synchronizing outputs of the module for comparing the average sedimentation rate of the oil product particles in the tank with the standard sedimentation rate, respectively, the information output of the base identification module the address of the height of the tank section is connected to another information input of the read signal generation module I am the average of the estimated allowable settling time of the oil product over the tank section, and the synchronizing output of the identification module of the base address of the height of the tank section is connected to the synchronizing input of the signal generation module for reading the average calculation over the allowable settling time of the oil product over the tank section.

The invention is illustrated by drawings, in which Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a specific structural implementation of a module for identifying a base address of an oil product section, Fig. 3 is an example of a specific constructive implementation of a module for identifying a base address of a tank page, in Fig. 4 is an example of a specific constructive implementation of a module for generating signal readout of parameters of a portion of a reservoir; FIG. 5 is an example of a specific constructive implementation of a parameter registration module s of the reservoir section, FIG. 6 is an example of a specific constructive implementation of a module for generating call signals of a subroutine for calculating the sedimentation rate of oil product particles, FIG. 7 is an example of a specific constructive implementation of a module for recording a sedimentation rate of particles of oil contamination, and FIG. 8 is an example of a specific constructive of the implementation of the selection module of the average sedimentation rate of the particles of oil product pollution over the reservoir section; Fig. 9 is an example of a specific constructive implementation of the module compared I am the average sedimentation rate of the oil product particles sedimentation rate with the standard sedimentation rate, Fig. 10 is an example of a specific constructive implementation of the module for identifying the base address of the height of the reservoir section, Fig. 11 is an example of a specific constructive implementation of the module for generating readout signals for the average of the reservoir portion is calculated -admissible time of sedimentation of the oil product, Fig. 12 is an example of a specific constructive implementation of the registration module of the average calculation and additional reservoir section Stim-time defending oil, 13 - an example of a specific implementation of the structural unit of issue settlement and the permissible time defending oil.

The system (Fig. 1) contains a module for identifying the base address of the oil product section, a module 2 for identifying the base address of the reservoir page, a module 3 for generating signals for reading parameters of the tank section, a module 4 for registering parameters for the tank section, a module 5 for generating call signals for the subroutine for calculating the sedimentation rate of the pollution particles of oil product, module 6 for recording the sedimentation rate of particles of oil pollution, module 7 for selection of the average particle sedimentation rate of the particle pollution of the reservoir petroleum product, module 8 for comparing the average reservoir sedimentation rate of the oil product particles with the standard sedimentation rate, module 9 for identifying the base address of the height of the reservoir, module 10 for generating signals for reading the average estimated reservoir settling time for the oil product in the reservoir, module 11 for recording the average section of the reservoir of the estimated allowable time of sedimentation of the oil product, module 12 of the issuance of the estimated allowable time of sedimentation of the oil product.

Figure 1 shows the first 15, second 16, third 17 and fourth 18 information inputs of the system, the first 19, second 20, third 21 and fourth 22 synchronizing inputs of the system, as well as address 23-24, information 25-28, synchronizing 31- 33 and signal outputs 34-37 of the system.

The oil product base address identification module 1 (FIG. 2) contains a register 40, a decoder 41, a memory module 42 made in the form of read-only memory (ROM), AND elements 43-45, OR element 46, delay elements 47-48. The drawing also shows information 50, synchronizing 51 and installation 52-53 inputs, information 62-67 and synchronizing 70 outputs.

Module 2 identifies the base address of the page of the tank (figure 3) contains a decoder 75, a memory module 76, made in the form of read-only memory (ROM), an adder 77, elements 78-80 And and elements 81-82 delay. The drawing also shows information 83-84 and synchronizing 85 inputs, information 86 and synchronizing 87 outputs.

The module 3 for generating signals for reading the parameters of the reservoir section (Fig. 4) contains a counter 89, a register 90, a decoder 91, a memory module 92 made in the form of read-only memory (ROM), an adder 93, elements 94-96 I, elements 97-98 OR and delay elements 99-102. The drawing also shows information 103-104, synchronizing 105, counting 106 and installation 107-108 inputs, information 109-110 and synchronizing 111 outputs.

Module 4 registration parameters of the section of the tank (figure 5) contains a register 115, an element 116 OR, and a delay element 117. The drawing also shows information 118, synchronizing 119 and installation inputs 120-122, information 123-126 and synchronizing 127 outputs.

The call signal generating module 5 of the subroutine for calculating the sedimentation rate of oil product particles (Fig. 6) contains a register 134, a counter 135, a comparator 136, an AND group of elements 137-138, an OR element group 139, an OR element 140-141, and delay elements 142-144 . The drawing also shows information 149-151, synchronizing 152-153 and installation 154 inputs, information 157 and synchronizing 158 outputs.

Module 6 registration of the sedimentation rate of particles of oil pollution (Fig.7) contains a counter 160, a register 161, an OR element 162 and delay elements 163-164. The drawing also shows information 165, synchronizing 166 and installation inputs 167-168, information 169-170 and synchronizing 171 outputs.

The module 7 selection of the average over a section of the reservoir sedimentation rate of particles of oil pollution (Fig) contains a shift register 175, a comparator 176, an adder 177, a group of 178-179 elements And, elements 180-181 And, element 182 OR and elements 183-185 delay . The drawing also shows informational 186-188, synchronizing 189 and installation 190-192 inputs, informational 195 and synchronizing 196-197 outputs.

Module 8 comparing the average over a portion of the reservoir sedimentation rate of oil product particles with the standard sedimentation rate (Fig.9) contains comparators 200-201, elements 202-203 And and element 204 delay. The drawing also shows information 205 - 208 and synchronizing inputs 209, synchronizing outputs 212-214.

Module 9 identifies the base address of the height of the section of the tank (figure 10) contains a decoder 215, a memory module 216, made in the form of read-only memory (ROM), elements 217-219 AND, element 220 OR and element 221 delay. The drawing also shows information 222 and clock inputs 223-224, information 225 and clock outputs 226.

The module 10 for generating read signals of the average over a portion of the tank estimated-acceptable sedimentation time of the oil product (Fig.11) contains a register 230, a decoder 231, a memory module 232, made in the form of read-only memory (ROM), adder 233, elements 234-236 And OR element 237 and delay elements 238-240. The drawing also shows information 241-242, synchronizing 243 and installation 244-246 inputs, information 247 and synchronizing 248 outputs.

The module 11 for recording the average over a portion of the reservoir estimated-acceptable settling time of the oil product (Fig) contains a register 255, an adder 256, an OR element 257 and delay elements 258-259. The drawing also shows information 260, synchronizing 261 and installation 262-264 inputs, information 265-266 and synchronizing 267 outputs.

The module 12 for issuing the estimated allowable settling time of the oil product (Fig) contains a comparator 270, groups 271-272 of elements And, elements 273-274 And and element 275 delay. The drawing also shows information 276-279 and synchronizing 280 inputs, information 283-284 and synchronizing 285-286 outputs.

All nodes and elements of the system are made on standard potential-impulse elements.

A remote workstation (AWP) of a system user consists of a terminal having a screen for displaying a query codegram and system signals, and a personal computer keyboard. Presentation of readable parameters of reservoir sections, sedimentation rates of contamination particles, average estimated and permissible time over a section of a reservoir, and estimated and admissible time over a reservoir are controlled from the server (not shown in the drawing).

The system operates as follows.

For each type of oil product poured into the tanks of the fueling complex (TZK), the system associates a certain section of the server database, and each tank with this type of oil product associates a page with the allocated memory section.

In this case, the read address of the parameters of any section of the tank in question is represented as a relative address shifted relative to the base address of the tank page by a code corresponding to the identifier of the processed section of the tank.

The parameters of the reservoir section are the temperature of the upper boundary of the section, the temperature of the lower boundary of the section, the height of the section and a certain number equal to the total number of temperature values in the section of the tank.

The system associates with each temperature of the reservoir section a value of the sedimentation rate of particles of oil product contamination. Next, the average sedimentation rate of the particles of oil product contamination is determined over the reservoir section and compared with the standard sedimentation rate of the particles of pollution to decide on the choice of operating mode.

The system associates with the height code of the reservoir section some base address of the height of the reservoir section, starting from which the server database stores the relative addresses of the ratios of the height of the reservoir section to the average sedimentation rate of oil pollution particles.

The offset code of each address of the ratio of the height of the reservoir section to the average on the plot of the sedimentation rate of the particles of oil contamination relative to the base address of the height of the reservoir section is determined as the correspondence to the code of the average on the plot of the sedimentation rate of the particles of oil contamination.

Namely, the code of the ratio of the height of the tank section to the average over the section of the tank sedimentation rate of particles of oil pollution is interpreted by the system as the code of the average over the section of the tank of the estimated allowable settling time of the oil product. The total average time for all sections of the tank is issued by the system to the user as the estimated allowable time of settling of the oil product.

Thus, using the identifiers of the oil product, the reservoir and its sections, it is possible to determine the estimated permissible settling time of the oil product as the average for each section of the tank and the total for the entire tank.

For this, the user of the system at his workplace generates a request codogram, which indicates the identifier of the oil product, the identifier of the tank, the identifier of the upper part of the tank, the identifier of the lower part of the tank, the density of the oil product under standard atmospheric conditions, the density of the pollution particle, the radius of the pollution particle and the standard particle settling rate oil product pollution:

The generated code from the workstation of the user of the system is fed to the information input 15 of the system and fed to the information input 50 of the identification module 1 of the base address of the oil product section and entered into register 40 by a synchronizing pulse supplied to the synchronizing input 51 of module 1 from the synchronizing input 19 of the system.

The oil product code from the output 54 of the register 40 is fed to the input of the decoder 41. The decoder 41 decrypts the oil product code and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 43-45 I. For definiteness, we assume that the high potential from the output of the decoder 41 will be open element 45 And one input.

The synchronizing pulse from the input 19 of the system, passing through the input 51, is delayed by the delay element 47 for the response time of the register 40 and the decoder 41 and enters through the element 45 And open to one input of a fixed cell of a read-only memory (ROM) 42. In a fixed cell of the ROM 42 the code of the base address of the petroleum product section is stored, the pages of which store information on the petroleum product parameters for all sections of each reservoir with the requested petroleum product.

The code of the base address of the oil product section from the output 62 of the ROM 42 is sent to the information input 84 of the module 2 for identifying the base address of the tank page and is fed to one input of the adder 77.

The reservoir code from the output 55 of the register 40 goes to the output 63 of the module 1 and is sent to the information input 83 of the module 2 and is fed to the input of the decoder 75. The decoder 75 decodes the tank code and generates at one of its outputs a high potential, which goes to the corresponding inputs of the elements 78- 80 I. For definiteness, suppose that a high potential from the output of the decoder 75 will open the element 80 And one input.

The synchronizing pulse from the output of the delay element 47 is delayed by the delay element 48 for the time of reading the fixed cell of ROM 42 of module 1 and the operation of the decoder 75 of module 2 and arrives through the element 80 And open at one input and to the input of the fixed cell of read-only memory (ROM) 76. In the fixed cell ROM 76 stores the offset code of the base address of the reservoir page relative to the base address of the section of the oil product. This code from the output of the ROM 76 is fed to another information input of the adder 77.

According to the synchronizing pulse from the output 70 of module 1, delayed by the delay element 81 for the time of reading the fixed cell of the ROM 76, in the adder 77, the codes supplied to its inputs are summed. From the output of the adder 77, the code of the base address of the reservoir page is removed, starting from which the oil product parameters for each section of the reservoir are stored in the server database.

The code of the base address of the tank page from the output 86 of module 2 is sent to the information input 104 of the module 3 for generating signals for reading the parameters of the tank section and fed to one information input of the adder 93.

The code of the upper part of the tank (the beginning of scanning) from the output 56 of the register 40 of module 1 is sent to the information input 103 of module 3 and fed to the information input of the counter 89, where it is recorded by the synchronizing pulse from the output of the delay element 81, delayed by the delay element 82 for the duration of the adder 77 and applied to the synchronizing input 105 of the module 3.

The code of the tank section from the output of the counter 89 is fed to the input of the decoder 91. The decoder 91 decrypts the code of the tank section and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 94-96 I. For definiteness, we assume that the high potential from the output of the decoder 91 element 95 And one input will be opened.

The synchronizing pulse from the input 105 of module 3 passes through the OR element 98, is delayed by the delay element 99 for the time the tank level code is entered into the counter 89 and the decoder 91 is activated, and enters through the 95 I element open at one input and to the input of a fixed cell of a read-only memory (ROM) 92 . In a fixed cell ROM 92 is stored code offset address of the section of the tank relative to the base address of the page of the tank. This code from the output of the ROM 92 is fed to another information input of the adder 93.

According to the synchronizing pulse from the output of the delay element 99, delayed by the delay element 100 for the read time of the fixed cell of the ROM 92, in the adder 93, the codes supplied to its inputs are summed. The output of the adder 93 is removed the code of the relative address of the upper section of the tank, which stores the parameters of the oil product of this section of the tank.

The code of the relative address of the upper section of the tank from the output of the adder 93 is fed to the information input of the register 90, where it is entered by the synchronizing pulse from the output of the delay element 100, delayed by the delay element 101 for the duration of the operation of the adder 93.

The same pulse from the output of the delay element 101 is delayed by the delay element 102 for the response time of the register 90 and from the output of the system 31 is fed to the input of the first server interrupt channel.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated at the address output 23 of the system and issuing the read parameters of the upper section of the tank to the information input 16 of the system.

The parameters of the read upper section of the tank from the information input 16 of the system are supplied to the information input 118 of the register 115 of the module 4 for registering the parameters of the tank section, where they are entered by the synchronizing pulse of the server received at the synchronizing input 119 of the register 115 from the input 20 of the system.

The same pulse from the input 119 of the module 4 is delayed by the delay element 117 and from the output 127 of the module 4 is sent to the synchronizing input 152 of the signal generation module 5 of the subroutine for calculating the sedimentation rate of the fuel pollution particles, the OR element 140 passes and enters the counting input of the counter 135, increasing it content per unit.

The counter 135 counts on an accrual basis the number of calls to the server database subroutine when processing the parameters of one section of the tank and forwards each time its contents to one information input of the comparator 136. To another information input 150 of the comparator 136 from the output 123 of module 4, the code of the total number of all calls of the subprogram server database for the cycle of processing parameters of one section of the tank.

The code of the total number of all calls to the server database subroutine for the cycle of processing the parameters of one section of the tank corresponds to the number of temperature parameters of the processed section of the tank.

According to the synchronizing pulse from the output of the OR element 140, delayed by the delay element 142 for the increment time of the counter 135 and supplied to the synchronizing input of the comparator 136, the comparator 136 compares the codes at its inputs.

Given that at the moment in time, only the first call to the server database routine was received, the contents of counter 135 will be less than the code for the total number of calls to the routine fed to input 150 of comparator 136 from output 123 of module 4.

In this case, a signal is generated at the output 155 of the comparator 136, which passes through the And elements of group 137 from the input 149 of module 5 the temperature code of the upper boundary of the upper section of the tank to the information input of the register 134, where it is entered by the synchronizing pulse from the output of the delay element 142, delayed by the element 143 delays for comparator response time 136.

The same pulse from the output of the delay element 143, delayed by the delay element 144 for the response time of the register 134, is output from the system 32 to the input of the second channel of the server interrupt.

With the arrival of this impulse, the server polls its information inputs and takes from the information output 25 of the system the temperature code of the upper boundary of the upper section of the tank, issued from the output of register 134 of module 5, and from the information output 26 of the system, the standard fuel density code, the particle density code and the radius code particles of pollution, issued from the output 58 of the register 40 of module 1, and returns them from its database to the information input 17 of the system in the form of a code for the sedimentation rate of the particles of pollution.

From the information input 17 of the system, the code for the sedimentation rate of the particles of pollution enters the information input 165 of the register 161 of module 6, where it is entered by the synchronizing pulse of the server, which is input to the system 21.

The same pulse from the input 166 of module 6 is delayed by the delay element 163 for the time the register is triggered and fed to the counter input of the counter 160, increasing its content by one. The counter 160 counts progressively the number of speed codes received in the register 161 from the server when processing the parameters of one section of the tank, and sends each time its contents to the information input 186 of the comparator 176 module 7.

To another information input 187 of comparator 176, output 123 of module 4 provides a code for the total number of all calls to the server database subroutine for a cycle of processing parameters of one section of the tank.

According to the synchronizing pulse from the output of the delay element 163, delayed by the element 164 for the increment of the counter 160 and supplied from the output 171 of the module 6 to the synchronizing input 189 of the module 7, the comparator 176 compares the codes at its inputs.

Given that at the moment in time, only the first result of the processing cycle of the parameters of the reservoir section was entered in register 161, the contents of the counter 160 equal to one will be less than the code for the total number of calls to the server database routine. In this case, a signal will appear at the output 193 of the comparator 176, which opens the element 180 AND on one input.

The synchronizing pulse from the input 189 of module 7, delayed by the delay element 183 for the response time of the comparator 176, passes through the element 180 and allows the passage of the code of the sedimentation rate of the oil pollution particles from the output 170 of the register 161 of the module 6 through the And elements of group 178 to one input of the adder 177.

The same pulse from the output of element 180 AND is supplied to the installation input 168 of module 6, the OR element 162 passes, and fed to the installation input of the register 161, preparing it for the next cycle of operation.

The same pulse from the output 196 of module 7 is supplied to the synchronizing input 153 of module 5, the OR element 140 passes, and enters the counting input of the counter 135, increasing its content by one.

The same pulse from the input 153 of the module 5 passes the element 141 OR and enters the installation input of the register 134, preparing it for the next cycle of work.

The new content of the counter 135 is fed to one information input of the comparator 136, to the other information input 150 of which, from the output 123 of module 4, the code of the total number of all calls of the server database routine for the processing cycle of the parameters of one section of the tank is supplied.

According to the synchronizing pulse from the output of the OR element 140, delayed by the delay element 142 for the increment time of the counter 135 and supplied to the synchronizing input of the comparator 136, the comparator 136 compares the codes at its inputs.

Given that at the moment in time, the second call to the subroutine call has already been accepted, the contents of counter 135 will be equal to the code of the total number of calls to the server database subroutine fed to input 150 of comparator 136 from output 123 of module 4.

In this case, a signal is generated at the output 156 of the comparator 136, which passes a temperature code of the lower boundary of the upper section of the tank through the AND elements of group 138 to the information input of the register 134, where it is entered by the synchronizing pulse from the output of the delay element 142, delayed by the delay element 143 for the time the comparator operates 136.

The same pulse from the output of the delay element 143, delayed by the delay element 144 for the response time of the register 134, is output from the system 32 to the input of the second channel of the server interrupt.

With the arrival of this impulse, the server polls its information inputs and takes from the information output 25 of the system the temperature code of the lower boundary of the upper section of the tank, issued from the output of register 134 of module 5, and from the information output of the system 26, the code for the standard density of the oil product, the code for particle density and the radius code particles of pollution, issued from the output 58 of the register 40 of module 1, and returns them from its database to the information input 17 of the system in the form of a code for the sedimentation rate of the particles of pollution.

From the information input 17 of the system, the code for the sedimentation rate of the particles of pollution enters the information input 165 of the register 161 of module 6, where it is entered by the synchronizing pulse of the server, which is input to the system 21.

The same pulse from the input 166 of module 6 is delayed by the delay element 163 for the time the register is triggered and fed to the counter input of the counter 160, increasing its content by one.

The new content of the counter 160 is fed to the information input 186 of the comparator 176 of the module 7. The other information input 187 of the comparator 176 from the output 123 of the module 4 is supplied with the code of the total number of all calls to the server database routine for the processing cycle of the parameters of one section of the tank.

According to the synchronizing pulse from the output of the delay element 163, delayed by the element 164 for the increment of the counter 160 and supplied from the output 171 of the module 6 to the synchronizing input 189 of the module 7, the comparator 176 compares the codes at its inputs.

Given that at the moment in time, the second call to the server database subroutine was already performed when processing the parameters of one section of the tank, the contents of the counter 160 will be equal to the code of the total number of calls to the server database subroutine. In this case, a signal appears on the output 194 of the comparator 176, which opens a single input element 181 And one input.

The synchronizing pulse from the input 189 of the module 7, delayed by the delay element 183 for the response time of the comparator 176, passes through the element 181 open at one input and allows the passage of the code for the sedimentation rate of the oil pollution particles, corresponding to the temperature of the lower boundary of the upper section of the tank, from the output 170 of the register 161 of the module 6 through the AND elements of group 179 to another input of the adder 177.

According to the same pulse, from the output of element 181 I, the adder 177 sums up the sedimentation rate codes for the particles of oil contaminants fed to its inputs, with the result being output to the information input of the shift register 175.

According to the pulse from the output of the element 181 AND, delayed by the delay element 184 for the operation time of the adder 177, the contents of the register 175 are shifted to the right by one digit and, in the form of a code of the average sedimentation rate of oil pollution particles, one section of the tank from the information output 195 of module 7 is sent to the information input 207 comparator 200 module 8 comparing the average over a section of the reservoir sedimentation rate of the particles of oil pollution with the standard sedimentation rate. At the other input 208 of the comparator 200, a code of the normative sedimentation rate of pollution particles from the output 67 of module 1 is supplied.

The clock pulse from the output of the delay element 184, delayed by the delay element 185 for the duration of the shift register 175, is output from the module 197 output 197 to the installation input 167 of module 6 and is supplied to the installation input of the counter 160, returning it to its original state.

The same pulse from the input 167 of module 6 passes through the OR element 162 and enters the installation input of the register 161 and resets its contents to zero, preparing it for the next cycle of operation.

The pulse from the output 197 of module 7 is also supplied to the installation input 154 of module 5 and is supplied to the installation input of the counter 135, returning it to its original state.

The same pulse from the input 154 of the module 5 passes the element 141 OR and is supplied to the installation inputs of the register 134, preparing it for the next cycle of work.

In addition, the pulse from the output 197 of the module 7 supplied to the synchronizing input 209 of the module 8 in the comparator 200 compares the codes of the speeds applied to its inputs,

If the code of the average on the site of the tank sedimentation rate of particles of oil pollution is greater than or equal to the code of the standard sedimentation rate, then at the output 211 of the comparator 200 a signal is generated that opens the element 203 And one input.

In this case, the synchronizing pulse from the input 209 of module 8, delayed by the delay element 204 for the response time of the comparator 200, passes through the element 203 And open at one input and, from the output 214 of the module 8, goes to the synchronizing input 223 of the module 9 for identifying the base address of the height of the tank section.

If the code of the average sedimentation rate of oil pollution particles in the tank section is less than the code of the standard sedimentation rate of oil pollution particles, then a signal is generated at the output 210 of the comparator 200, which opens the element 202 And at one input.

In this case, the synchronizing pulse from the input 209 of module 8, delayed by the delay element 204 for the time the comparator 200 operates, passes through the And element 202 open to one input to the synchronizing input of the comparator 201.

Since the system allows a lower than the standard average sedimentation rate of oil pollution particles only in the lower section of the tank, the code of each current section of the tank, the parameters of which are currently being processed by the system, is checked for compliance with the code of the lower section of the tank.

To do this, the input 205 of the comparator 201 is supplied with the code of the currently processed tank section from the output 110 of the module 3, and the input of the comparator 206 is the code of the lower section of the tank from the output 65 of the module 1.

If the average settling rate of particles of oil product contamination in the treated area is less than the normative, and the site codes at the inputs of the comparator 201 do not match, then the output "Oil is not ready for output" is generated at the output 213 of the comparator 201. This signal from the output 213 of the comparator 201 is fed to the signal output 34 of the system and sent to the automated workstation (AWP) of the user of the system, who set the initial codogram of the request for input 15 of the system.

In parallel with the issuance by the user of the system of the system from the output 213 of the module 8 of the oil product unavailability signal to the output of this signal, the system is reset and returned to its original state.

For this, the signal from the output 213 of module 8 is supplied to the installation input 52 of module 1, the OR element 46 passes, and enters the installation input of register 40, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 213 of module 8 is supplied to the installation input 107 of module 3, the OR element 97 passes, and enters the installation input of the counter 89, returning it to its original state.

The same signal from the output 213 of module 8 is supplied to the installation input 120 of module 4, the OR element 116 passes, and enters the installation input of register 115, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 213 of module 8 is supplied to the installation input 190 of module 7, the OR element 182 passes, and enters the installation input of the shift register 175, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 213 of module 8 is supplied to the installation input 244 of module 10, the OR element 237 passes, and enters the installation input of the register 230, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 213 of module 8 is supplied to the installation input 262 of module 11, the OR element 257 passes, and enters the installation input of register 255, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

If the sedimentation rate of particles of oil product contamination, the average on the treated section of the tank, is lower than the normative, and the codes of the sections at the inputs of the comparator 201 are the same, then at the output 212 of the comparator 201 the signal “Oil is ready to issue” is generated. This signal from the output 212 of the comparator 201 is sent to the signal output 35 of the system and sent to the workstation (AWP) of the user of the system, who set the initial codogram of the request for input 15 of the system.

The same signal from the output 212 of module 8 is supplied to the synchronizing input 224 of module 9 for identifying the base address of the height of the tank section.

At the information input 222 of module 9, the code for the height of the tank section from the output 126 of module 4 is supplied to the input of the decoder 215. The decoder 215 decodes the code for the height of the tank section and generates a high potential at one of its outputs, which goes to the corresponding inputs of elements 217-219 I. For definiteness, suppose that a high potential from the output of the decoder 215 will open the element 217 And one input.

Each synchronizing pulse from inputs 223 and 224 of module 9, passing through an OR element 220, also passes through an element 217 And open at one input to the input of a fixed cell of a read-only memory device (ROM) 216. A code of the base address of the section height is stored in a fixed cell of the ROM 216 reservoir, starting from which the server’s database contains codes for the estimated allowable time of sedimentation of the oil product, the average height of the reservoir section, each of which corresponds to the code of the average sedimentation rate of pollution particles n oil products through on this site.

The code of the base address of the height of the tank section from the output 225 of module 9 is sent to the information input 242 of the module 10 for generating signals for reading the average calculated-permissible settling time of the oil product over the tank section and goes to one information input of the adder 233.

Each receipt of the code of the average site sedimentation rate of oil product particles at the input by the decoder 231 from the output of module 195 7 is decrypted by the decoder with the generation of high potential at one of its outputs. This potential from one of the outputs of the decoder is supplied to the corresponding inputs of the elements 234-236 I. For definiteness, suppose that the high potential from the output of the decoder 231 will open the element 235 And one input.

In this case, the synchronizing pulse from the output of the element 220 OR module 9, delayed by the element 221 of the delay for reading the fixed cell ROM 216, when it enters the input 243 of the module 10 from the output 226 of the module 9 passes through the element 235 And open to the reading input fixed to one cells of read-only memory (ROM) 232.

In a fixed cell of ROM 232, a code is stored for the offset address of the reading of the average calculated-permissible settling time of the oil product over the site, corresponding to the code of the average sedimentation rate of the oil product particles in this section and received at the input of the decoder 231, relative to the base address of the height of the tank section already located at one input adder 233.

The offset code of the address of the average of the estimated permissible settling time of the oil product from the output of the ROM 232 is supplied to the other input of the adder 233.

According to the synchronizing pulse from the input 243 of the module 10, delayed by the delay element 238 for the time of reading the fixed cell of the ROM 232, in the adder 233 the codes received at its inputs are summed up, with the relative address of reading the average settlement time allowable oil product settling at the register input 230.

The synchronizing pulse from the output of the delay element 238, the delayed delay element 239 for the operation time of the adder 233, the relative address of the reading of the average over the area of the estimated allowable settling time of the oil product is entered in the register 230.

The same pulse from the output of the delay element 239, delayed by the delay element 240 for the response time of the register 230, is output from the system output 33 to the input of the first server interrupt channel.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 24 of the system, and issuing a read code of the average calculated-allowable settling time of the oil product over the information section 18 of the system.

From the information input 18 of the system, the code of the average of the estimated allowable settling time of the oil product is fed to the information input 260 of register 255 of module 11 for registering the average of the estimated allowable settling time of the oil product in the reservoir section, where it is entered by the server's synchronizing impulse to the system input 22.

The same server pulse from the input 261 of the module 11, the delayed delay element 258 for the response time of the register 255, the code of the average calculated-allowable settling time of the oil product, received at the summing input of the adder 256, is entered into the adder 256.

The same pulse from the output of the delay element 258, delayed by the delay element 259 for the operation time of the adder 256, is output from the output 267 of the module 11 to the synchronizing input 280 of the module 12 for issuing the estimated allowable settling time of the oil product.

According to this pulse, from the input 280 of module 12, which is supplied to the synchronizing input of the comparator 270, the comparator 270 controls the completion of scanning of sections of the tank by comparing the codes of the sections supplied to its inputs.

For this purpose, the code of the current processed section of the tank is supplied to one input 277 of the comparator 270 from the output 110 of the module 3, and the code of the lower section of the tank is sent to the other input 278 of the comparator 270 from the output 65 of the module 1.

If the code of the current processed section of the tank at the inlet 277 of the comparator 270 is not equal to the code of the lower section of the tank at the input 278 of the comparator 270, then, therefore, the scanning and processing of the parameters of the sections of the tank is not yet complete.

In this case, a signal is generated at the output 281 of the comparator 270, which opens the I 273 element one input. Then, the synchronizing pulse from the input 280 of the module 12, delayed by the delay element 275 for the time the comparator 270 operates, passes through the I element 273 I open at one input and allows the issuance of the average code of the estimated allowable time for settling the oil product from the input 276 of module 12 through the elements And 271 of the group to the information output 29 of the system, from where it is sent to the user's workstation.

The issue on the user's automated workstation of a code of the average calculated-permissible settling time of the oil product over the tank section is accompanied by the issuance of the signal “The average calculated-permissible settling time of the oil-product over the tank section” signal from the system output 36 of the user’s workstation.

Since not all sections of the tank have yet been scanned and processed, this signal from the output 285 of module 12 is used to prepare the system for operation in the next cycle.

To do this, the signal from the output 285 of module 12 is supplied, firstly, to the installation inputs of all those modules that will be used by the system when processing the parameters of the next section of the tank.

For this, the signal from the output 285 of module 12 is supplied to the installation input 121 of module 4, the OR element 116 passes, and enters the installation input of register 115, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 285 of module 12 is supplied to the installation input 191 of module 7, the OR element 182 passes, and enters the installation input of the shift register 175, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 285 of module 12 is supplied to the installation input 245 of module 10, the OR element 237 passes, and enters the installation input of the register 230, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 285 of module 12 is supplied to the installation input 263 of module 11, the OR element 257 passes, and enters the installation input of register 255, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

Secondly, the signal from the output 285 of the module 12 is fed to the counting input 106 of the module 3, which forms the read signals of the parameters of the next section of the tank.

The newly generated synchronizing pulse, issued from the output 111 of the module 3 to the output 31 of the system, is again fed to the input of the first channel of the server interrupt.

With the arrival of this impulse, the server again switches to the subprogram for interrogating the contents of its database at the newly formed address, issued from the output of register 90 to the address output 23 of the system, and issuing the read parameters of the next section of the tank to the information input 16 of the system.

The described process of generating and selecting addresses of reservoir sections from the memory of the server database with subsequent processing of the parameters of each section of the reservoir will continue until not only addresses of all sections of the reservoir have been selected from the memory of the server database, but also the parameters of each section of the reservoir have been processed.

This will happen when the code of the current processed section of the tank supplied to the input 277 of the comparator 270 from the output 110 of the module is equal to the code of the lower (final) section of the tank supplied to the input 278 of the comparator 270 from the output 65 of the module 1.

With the coincidence of the codes of the sections of the tank at the inputs 277 and 278 of the comparator 270, a signal is generated already at the output 282 of the comparator 270. This signal opens one input element 274 I.

In this case, the synchronizing pulse from the input 280 of module 12, delayed by the delay element 275 for the response time of the comparator 270, passes through the I element 274 open at one input and allows the issuance of a code of the estimated allowable settling time of the oil product from the input 279 of the module 12 through the elements 272 And groups to the information output 30 of the system, from where it is sent to the workstation of the user of the system.

The issuance on the user's workstation of the code of the estimated allowable time of settling of the oil product is accompanied by the issuance of the signal on the user's workstation of the “Estimated allowable time of settling of the oil” signal output 37 of the system.

The same signal from the output 286 of the module 12 is fed to the installation inputs of all the modules of the system to prepare them for work to process the next codogram of the system user request received at the information input 15 of the system.

To this end, the signal from the output 286 of module 12 is supplied to the installation input 122 of module 4, the OR element 116 passes, and enters the installation input of the register 115, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 286 of module 12 is supplied to the installation input 192 of module 7, the OR element 182 passes, and enters the installation input of the shift register 175, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 286 of module 12 is supplied to the installation input 246 of module 10, the OR element 237 passes, and enters the installation input of the register 230, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 286 of module 12 is supplied to the installation input 264 of module 11, the OR element 257 passes, and enters the installation input of register 255, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 286 of module 12 is supplied to the installation input 53 of module 1, the OR element 46 passes, and enters the installation input of the register 40, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

The same signal from the output 286 of module 12 is supplied to the installation input 108 of module 3, the OR element 97 passes, and enters the installation input of register 90, resetting its contents to zero and preparing it, thereby, for a new operation cycle.

In addition, the same signal from the output of the OR element 97 is supplied to the installation input of the counter 89, returning it to its original state.

Thus, the introduction of new nodes and modules and new structural connections has significantly improved system performance by eliminating data retrieval across the entire system server database.

Information sources

1. US Patent No. 5136708, M.C. G06F 15/16, 1992.

2. US Patent No. 5129083, M.C. G06F 12/00, 15/40, 1992 (prototype).

3. Timoshenko A.N., Gryadunov K.I. A mathematical model of gravitational cleaning of fuels from mechanical impurities. / Association of Civil Aviation Aircraft Fuel Supply Organizations: Information Digest. - Moscow: OATO VS GA, No. 5, 2010. P.46-47.

4. Commodity petroleum products, their properties and applications. Directory. Ed. N.G. Puchkova. - M., 1971.

Claims (1)

A system for optimizing the time of settling of petroleum products in storage tanks depending on the distribution of the temperature of the petroleum product over the height of the tank, containing a module for identifying the base address of the petroleum product section, the information input of which is the first information input of the system designed to receive the request codogram from the workstation of the system user, synchronizing the module input identification of the base address of the petroleum product section is the first synchronizing input of a system designed to receive synchronization signals of entering the request codogram from the workstation of the system user into the identification module of the base address of the oil product section, the first information output of the identification module of the base address of the oil product section is the first information output of the system designed to issue codes of standard oil product density, density and radius particles of oil pollution to the first information input of the database server, module of generating signals for reading parameters of the reservoir section, one information input of which is connected to the second information output of the identification module for the base address of the oil product section, one information output of the module for generating signals for reading the parameters of the reservoir section is the first address output of the system designed to provide the address of the reservoir section to the address input of the base server data, and the synchronizing output of the module for generating signals for reading the parameters of the reservoir section is the first synchronizing output of the system, intended for issuing control signals by reading the parameters of the tank section to the input of the first channel server interrupt channel, the module for registering the parameters of the tank section, the information input of which is the second information input of the system, designed to receive codes of the parameters of the tank section read from the database the server, the synchronizing input of the module for registering the parameters of the reservoir section is the second synchronizing input of the system, before assigned to receive signals of entering codes of the parameters of the reservoir section, read from the server database, into the module for registering the parameters of the reservoir section, the module for recording the sedimentation rate of particles of oil pollution, the information input of which is the third information input of the system, designed to receive codes of the sedimentation rate of particles of oil pollution, read from the server database, the synchronizing input of the module for recording the sedimentation rate of particles of oil pollution is the third synchronizing input of the system, designed to receive signals for entering the sedimentation rate codes of oil pollution particles read from the server database into the module for registering the sedimentation rate of oil pollution particles, a module for generating signals for reading the average acceptable settlement time of the oil product over the tank section, the information output of which is the second address output of the system, designed to provide the address of the average over the area of the tank settlement-allow the time of sedimentation of the oil product to the address input of the database server, and the synchronizing output of the module for generating the readout signals of the average calculated-allowable settling time of the oil product over the tank section is the second synchronizing output of the system designed to provide control signals for reading the average of the calculation over the section of the reservoir tank of the estimated allowable oil settling time to the input of the first channel of the database server interruption, the module for registering the average the permissible settling time of the oil product, the information input of which is the fourth information input of the system, designed to receive codes of the estimated average allowable settling time of the oil product over the tank section, read from the server database, which synchronizes the input of the registration module for the average estimated settling time over the tank section of the tank oil product is the fourth synchronizing input of the system, designed to receive signals of entering codes of secondary the installation of the reservoir of the estimated allowable settling time of the oil product, read from the server database, into the module for registering the average over the section of the tank of the estimated acceptable settling time of the oil product, the module for issuing the estimated allowable time of settling of the oil product, the first information input of which is connected to the other information output of the signal generation module reading the parameters of the tank section, the second information input of the module for issuing the estimated allowable settling time of the oil product It is connected to the third information output of the module for identifying the base address of the oil product section, and the third and fourth information inputs of the module for issuing the estimated allowable settling time of the oil product are connected to the first and second information outputs of the module for recording the average of the calculated section of the tank for the estimated oil settling time, synchronizing module input issuing the estimated allowable settling time of the oil product is connected to the synchronizing output of the regis module a walkie-talkie of the average calculated-allowable settling time of the oil product over the tank section, one information output of the module for issuing the calculated-allowable settling time of the oil product is the second information output of the system designed to issue codes of the average calculated over the allowed tank settling time of the oil product to the automated workstation of the system user, another information output of the module for issuing the estimated allowable settling time of the oil product is the third a system output intended for issuing a code for the estimated allowable settling time of the oil product at the user's computer workstation, one synchronizing output module for issuing the calculated allowable settling time of the oil product is connected to the counting input of the module for generating signals for reading parameters of the tank section, with the first installation input of the registration module parameters of the tank section, with the first installation input of the module for generating signals for reading the average part of the reservoir of the estimated allowable time of settling of the oil product, with the first installation input of the module for recording the average of the estimated portion of the reservoir of sediment of the oil product and is the first signal output of the system designed to provide an identification signal of the average of the section of the reservoir of the estimated permissible time of settling of oil automated workstation of the system user, another synchronizing output of the module for issuing the estimated allowable time the stagnation of the oil product is connected to the second installation input of the signal generation module for reading the average calculated over the allowable settling time period for the oil product, with the second installation input module for recording the average estimated tank allowable settling time for the oil section, with the second installation input for the module for registering the tank section parameters, s one installation input of the module identifying the base address of the oil product section, with one installation input of the module forming signal readout of the parameters of the tank section, and at the same time it is the second signal output of the system, intended for issuing an identification signal for the estimated allowable settling time of the oil product at the user's computer workstation, characterized in that it contains a module for identifying the base address of the tank page, the first and second information whose inputs are connected to the fourth and fifth information outputs of the module identifying the base address of the section of the oil product respectively, and the synchronizing input of the identification module of the base address of the reservoir page is connected to the synchronizing output of the identification module of the base address of the oil product section, the information output of the identification module of the base address of the tank page is connected to another information input of the module for generating signals for reading the parameters of the tank section, and the synchronizing output of the base address identification module the page of the tank is connected to the synchronizing input of the counting signal generation module the parameters of the reservoir section, the module for generating call signals of the subroutine for calculating the sedimentation rate of oil product particles, the first, second and third information inputs of which are connected to the first, second and third information outputs of the module for registering parameters of the tank section, respectively, one clock input of the module for generating the signals for calling the calculation routine the sedimentation rate of the particles of oil pollution is connected to the synchronizing output of the steam registration module ameter of the tank section, the information output of the module for generating call signals of the subroutine for calculating the sedimentation rate of particles of oil contamination is the fourth information output of the system designed to provide the temperature code of the tank section for the second information input of the database server, and the synchronizing output of the module for generating signals for the call of the module for the subroutine of calculating the particle sedimentation rate contamination of the oil product is the third synchronizing system output designed for I issue call control signals of a subroutine for calculating the sedimentation rate of oil product particles at the input of the second interrupt channel of the database server, a selection module for the average oil sedimentation particle sedimentation rate over the section of the tank, the first information input of which is connected to the first information output of the module for recording the parameters of the tank section, and the second and the third information inputs of the selection module of the average over the section of the reservoir sedimentation rate of particles of oil pollution by are connected to the first and second information outputs of the module for registering the sedimentation rate of oil pollution particles, respectively, the synchronizing input of the selection module for the average sedimentation rate of the particles of oil pollution in the reservoir is connected to the synchronizing output of the module for registering the sedimentation rate of oil particles, and the first and second installation inputs of the medium selection module over a section of the reservoir, the sedimentation rates of the particles of oil pollution are connected to one and the other timing outputs of the module for calculating the estimated allowable time of settling of the oil product, respectively, the information output of the selection module of the average sedimentation rate of the particles of oil contamination of the oil product is connected to one information input of the signal generation module for reading the average of the calculated part of the tank of the settling time of the oil product, one synchronizing output of the selection module average over a section of the reservoir sedimentation rate of particles of oil pollution is connected with dr with a synchronizing input of the module for generating signal signals of the subprogram for calculating the sedimentation rate of the particles of oil pollution and with one installation input of the module for registering the sedimentation particles of the oil product, the other synchronizing output of the module for selecting the average sedimentation rate of particles of the oil product is connected to the installation input of the module for generating signal signals of the subprogram calculating the sedimentation rate of particles of oil pollution and with another setting the input of the module for registering the sedimentation rate of oil pollution particles, a module for comparing the average sedimentation rate of the oil pollution particles with the standard sedimentation rate, the first information input of which is connected to the information output of the selection module of the average particle sedimentation rate of the oil pollution particles, the second information input of the module comparing the average over a section of the reservoir sedimentation rate of particles of oil pollution with the standard rate sedimentation is connected to another information output of the module for generating signals for reading the parameters of the tank section, and the third and fourth information inputs of the module for comparing the average sedimentation rate of the oil product particles with the standard sedimentation rate are connected to the third and sixth information outputs of the module for identifying the base address of the oil product section, respectively, the synchronizing input of the module for comparing the average particle sedimentation rate over a portion of the reservoir is dirty I of a petroleum product with a standard sedimentation rate is connected to another synchronizing output of the selection module of the average sedimentation rate of the oil contamination particles in the reservoir, the first synchronizing output of the module for comparing the average sedimentation rate of the oil contamination particles of the reservoir with the normative sedimentation rate is connected to another installation input of the read signal generation module parameters of the tank section, with the third installation input of the read signal generation module I average of the calculated-permissible settling time of the oil product across the reservoir section, with the third installation input of the registration module of the average calculated-permissible settling time of the petroleum product from the reservoir section, with the third installation input of the selection module of the selection of the average sedimentation rate of the oil contamination particles over the reservoir section, with the third installation input of the module registration of the parameters of the reservoir section, with a different installation input of the identification module of the base address of the oil product section and at the same time I is the third signal output of the system, intended for issuing to the user’s automated workstation a system of the oil product unavailability for issuing, the second synchronizing output of the module for comparing the average sedimentation rate of the oil product particles with the standard sedimentation rate is the fourth signal output of the system, intended for issuing to the automated the workplace of the user of the oil readiness for delivery system, and the identification module the basic address of the height of the tank section, the information input of which is connected to the fourth information output of the module for registering the parameters of the tank section, and the first and second synchronizing inputs of the identification module of the base address of the height of the tank section are connected to the second and third synchronizing outputs of the module for comparing the average particle settling rate of the pollution particles oil product with a standard sedimentation rate, respectively, the information output of the base address identification module and the height of the reservoir section is connected to another information input of the module for generating readout signals of the average calculated-admissible settling time of the oil product over the tank section, and the synchronizing output of the identification module for the base address of the height of the reservoir section is connected to the synchronizing input of the module for generating signals for reading the signals of the average reading over the reservoir section of the estimated acceptable time sedimentation of oil products.

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