RU2399026C2 - System for controlling communal services - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: system has a voltage sensor, a current sensor, a flow sensor for hot water, cold water and gas, a device for converting signals of consumed current voltage into a consumed power signal, a control unit, a block of sensors, a controller, a liquid-crystal display, a transmitting device, galvanic isolation units, an addressing unit, a sampling unit, a voltage control unit, a hot water pressure sensor and a hot water pressure control unit, a hot water temperature sensor and a hot water temperature control unit, a cold water pressure sensor and a cold water pressure control unit, a gas pressure sensor and a gas pressure control unit, a gas temperature sensor and a gas temperature control unit and a time pulse generator. The system also comprises a cold water pressure sensor, gas and hot water pressure and temperature sensors, corresponding units for monitoring quality of rendered services through which potential type signals such as voltage, pressure and temperature are controlled. From the control results, quality coefficients of services rendered are calculated in the control unit and payment for services is calculated taking into account the number of services and their quality.

EFFECT: determination of quality of communal services during use by a consumer so as to account for the quality of services when calculating payment for said services.

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Description

The invention relates to the field of measuring and computing technology and is used to control the provision and consumption of various types of utilities in control systems for the consumption of electricity, gas, cold and hot water, thermal energy. The invention can be applied in public utilities for household consumers.

Utility control consists of two parts: control of service consumption, which records consumption signals such as current consumption for electricity, gas, hot and cold water consumption, and quality control of service delivery, which measures potential signals such as voltage in electric networks, pressure in pipelines of gas, water and heating, temperature of hot water.

If the signals from the flow sensors depend on the actions of the consumer, and this is the number of services used, then the signals from the potential sensors are determined by the supplier, and they characterize the quality of the service. Since the consumer uses the services at his discretion, he needs to measure potential signals (determine the quality of the service), for example, the voltage in the mains, only when he consumes the service. The quality of the service at another time does not interest him.

The consumed amount of energy for any energy carrier is calculated by measuring the flow and potential signals, and its quality is determined by potential signals.

Existing utility control systems measure utilities consumption signals, and potential signals measure only to determine energy consumption.

Thus, there is the technical task of determining the quality of utilities with a view to its consideration when paying for services.

A known control system of housing and communal information (RU, patent No. 2141626, publ. 20.11.99, bull.no 32), which contains home controllers with storage devices containing addresses of houses, modems, an electronic computer of the central control room with a timer for remembering the event in time and with a printer for providing legal record keeping and printing of invoice receipts payable by tenants, personal computers with sound and light alarms, located in duty guards, param sensors ditch of work with help desks, cable, postal, telephone and / or radio channels, unified sensors of electrical signals for temperature, pressure and volumetric flow of gas, sensors of electrical signals for temperature and volumetric flow of water, located at characteristic points of heating systems of apartments, systems drinking and hot water, microcontrollers made with the possibility of storing apartment numbers and determining the mass gas flow and drinking water consumption, energy content of hot water and heat, taking into account ohm of temperature error and storing these values for the period of absence of mains power, equipped with autonomous power sources, electronic converter units with network power sources, security assistance call desks, and also contains blocks of apartment meters of actually consumed gas by its mass, heat and electric energy, drinking water and energy content of hot water, made in the form of electromechanical counters of electrical impulses corresponding to a given "single" ra consumed energy carriers with the possibility of their placement outside the apartments, while sensors and security assistance call panels are connected via electronic converters to microcontrollers, which are connected to apartment meter units and home controllers, connected via modems and communication channels to the central control room electronic computer and PC duty units of the fire brigade, police, ambulance, emergency gas service, housing and communal services or elevator services, located laid near the house, whose tenants need help.

Common features of the well-known analogue system and the proposed system are the presence of a controller that determines the flow of electricity, gas, drinking and hot water, standardized voltage, current, electric signal sensors by temperature, pressure and volumetric flow of gas and hot water, pressure sensors and volumetric drinking water costs.

The reason that impedes the achievement of the technical task is that there are no service quality control channels in the analogue system, as a result of which potential type signals that characterize the quality of service delivery, such as voltage, pressure, temperature, are not processed separately from flow control signals utilities.

A known accounting system of utility services at a variable tariff (RU, Patent No. 2134865, publ. 20.08.99, bull. No. 23), containing the first channel, consisting of a pulse converter, the output of which is connected to the input of the first conversion device, and a counter, a determination unit parameters, the output of which is connected to the input of the memory block, n-1 channels, consisting of a counter and series-connected pulse converter and a conversion device, the memory block is made in the form of a non-volatile memory block, while in each channel the output even devices connected via a counter with a corresponding input parameter determination unit, respective outputs of which are connected to second inputs of scaling circuits and counters and display channel, and the block determining parameter and output input-volatile memory block are formed as entry and exit.

Common features of the known analogue system and the proposed system are the presence of a converter, counters and controller (control unit).

The reason that impedes the achievement of the task is that the analogue system does not have quality control units for the provision of services, and potential type signals that characterize the quality of service delivery are not processed separately from the service flow control signals.

A well-known utility metering system and energy meter, which is used in it, (UA, declaration patent for invention No. 63853, publ. 15.01.04, bull. No. 1), which we have chosen as a prototype and consists of a current sensor, voltage sensor , flow sensors for hot water, cold water and gas, from a control unit, a power to frequency converter, a sensor unit, galvanic isolation units, an addressing unit and a sensor interrogation unit, a liquid crystal indicator, a transmitting device, a default indicator, and the sensor current and voltage ki are connected to the inputs of the power converter to the frequency, the output of which and the output of the sensor unit are connected respectively to the first and second inputs of the control unit, to the third and fourth input-outputs of which, through the galvanic isolation units, the addressing unit and the sensor polling unit are connected, respectively, to the inputs of which are connected to the outputs of the sensors for the flow of cold water, hot water and gas, while the first output of the control unit is connected to the controller connected to the liquid crystal display, Ora output control unit via galvanic isolation unit connected to the transmitting device, and its third output - with an indicator of non-payment.

Common features of the prototype system and the proposed system are the presence of a voltage sensor, current sensor, flow sensors for hot water, cold water and gas, a converter, a control unit, a sensor unit, a controller, a liquid crystal indicator, a transmitting device, galvanic isolation units, an addressing unit, a unit polling sensors, and the outputs of the current and voltage sensors are connected to the inputs of the converter, the output of which and the output of the sensor unit are connected respectively to the first and second inputs of the control unit a unit, to the third and fourth inputs and outputs of which, through the galvanic isolation blocks, the addressing unit and the sensor polling unit are connected, respectively, the outputs of the hot water, cold water, gas flow sensors are connected to one of its inputs, while the first output of the control unit is connected to the controller input the output of which is connected to the input of the liquid crystal indicator, the second output of the control unit is connected to the input of the galvanic isolation unit, the output of which is connected to the input of the transmitting device, the output to torogo is output system.

The reason that impedes the achievement of the task is that the analogue system does not have quality control units for the provision of services, and potential type signals that characterize the quality of service delivery are not processed separately from the service flow control signals.

The basis of the invention is the task of determining the quality of utilities for the time they are consumed by the consumer in order to take it into account when calculating the payment for consumed utilities.

The problem is solved in that in a utility control system, which consists of a voltage sensor, current sensor, flow sensors for hot water, cold water and gas, a converter, a control unit, a sensor unit, a controller, a liquid crystal indicator, a transmitting device, galvanic isolation units, block addressing, block polling sensors, and the outputs of the current and voltage sensors are connected to the inputs of the Converter, the output of which and the output of the sensor block are connected respectively to the first and second inputs of the block board, to the third and fourth inputs and outputs of which, through the galvanic isolation blocks, the addressing unit and the sensor polling unit are connected, to one of the inputs of which the outputs of the flow sensors of hot water, cold water, gas are connected, while the first output of the control unit is connected to the controller input the output of which is connected to the input of the liquid crystal indicator, the second output of the control unit is connected to the input of the galvanic isolation unit, the output of which is connected to the input of the transmitting device, in the course of which is the output of the system, in accordance with the invention, a voltage control unit, a hot water pressure sensor and a hot water pressure control unit, a hot water temperature sensor and a hot water temperature control unit, a cold water pressure sensor and a cold water pressure control unit, a sensor are additionally introduced gas pressure and gas pressure control unit, gas temperature sensor and gas temperature control unit, temporary pulse generator, and the output of the voltage sensor is connected to the first input of the con a voltage role, to the second input of which a current sensor is connected, the output of the hot water pressure sensor is connected to the first input of the hot water pressure control unit, the output of the hot water temperature sensor is connected to the first input of the hot water temperature control unit, the output of the hot water flow sensor is connected to the second inputs pressure and hot water temperature control units, the output of the cold water pressure sensor is connected to the first input of the cold water pressure control unit, the second input of which is connected to the date output cold water flow sensor, the output of the gas pressure sensor is connected to the first input of the gas pressure control unit, the output of the gas temperature sensor is connected to the first input of the gas temperature control unit, the output of the gas flow sensor is connected to the second inputs of the pressure and gas temperature control units, the output of the time pulse generator connected to the third inputs of all control units, the address output of the addressing unit is connected to the fourth inputs of all control units, the reset output of the addressing unit is connected to the fifth inputs of all control units control outputs of all control units connected to a respective input of survey sensors.

Introduction to the system of a voltage control unit, a hot water pressure sensor and a hot water pressure control unit, a hot water temperature sensor and a hot water temperature control unit, a cold water pressure sensor and a cold water pressure control unit, a gas pressure sensor and a gas pressure control unit, a sensor the temperature of the gas and the gas temperature control unit, a temporary pulse generator, the output of the voltage sensor connected to the first input of the voltage control unit, to the second input of which a sensor is connected to the current, the output of the hot water pressure sensor is connected to the first input of the hot water pressure control unit, the output of the hot water temperature sensor is connected to the first input of the hot water temperature control unit, the output of the hot water flow sensor is connected to the second inputs of the pressure and hot water temperature control units, the output of the cold water pressure sensor is connected to the first input of the cold water pressure control unit, the second input of which is connected to the output of the cold water flow sensor, the output of the gas pressure sensor is connected nen with the first input of the gas pressure control unit, the output of the gas temperature sensor is connected to the first input of the gas temperature control unit, the output of the gas flow sensor is connected to the second inputs of the pressure and gas temperature control units, the output of the temporary pulse generator is connected to the third inputs of all control units, address the output of the addressing unit is connected to the fourth inputs of all control units, the output of the addressing unit is connected to the fifth inputs of all control units, the outputs of all control units are connected to the corresponding input of the sensor interrogation unit, which made it possible to determine the quality of power supply, hot water, cold water, gas and take into account quality indicators for the corresponding payment of utility bills.

The utility control system, the block diagram of which is shown in FIG. 1, consists of a voltage sensor 1, a current sensor 2, hot water flow sensors 3, cold water 4 and gas 5, a converter 6, a control unit 7, a sensor unit 8, a controller 9, a liquid crystal indicator 10, a transmitting device 12, galvanic isolation units 11, 13, 15, an addressing unit 14, a sensor polling unit 16, a voltage monitoring unit 22.1, a hot water pressure sensor 17 and a hot water pressure monitoring unit 22.2, a hot water temperature sensor 18 and block A portion of the hot water temperature 22.3, the cold water pressure sensor 19 and the cold water pressure control unit 22.4, the gas pressure sensor 20 and the gas pressure control unit 22.5, the gas temperature sensor 21 and the gas temperature control unit 22.6, the time pulse generator 23, the current sensor outputs 2 and voltage 1 are connected to the inputs of the converter 6, the output of which and the output of the sensor unit 8 are connected respectively to the first and second inputs of the control unit 7, to the third and fourth inputs-outputs of which are through galvanic isolation blocks Calls 13, 15 are connected respectively to the addressing unit 14 and the sensor polling unit 16, to one of the inputs of which the outputs of the flow sensors for hot water 3, cold water 4, gas 5 are connected, while the first output of the control unit 7 is connected to the input of the controller 9, the output of which connected to the input of the liquid crystal indicator 10, the second output of the control unit 7 is connected to the input of the galvanic isolation unit 11, the output of which is connected to the input of the transmitting device 12, the output of which is the output of the system, the output of the voltage sensor 1 is connected connected to the first input of the voltage control unit 22.1, the current sensor 2 is connected to the second input, the output of the hot water pressure sensor 17 is connected to the first input of the hot water pressure control unit 22.2, the output of the hot water temperature sensor 18 is connected to the first input of the hot water temperature control unit 22.3, the output of the hot water flow sensor 3 is connected to the second inputs of the pressure control units 22.2 and the hot water temperature 22.3, the output of the cold water pressure sensor 19 is connected to the first input of the cold water pressure control unit 22.4, the second input of which is connected to the output of the cold water flow sensor 4, the output of the gas pressure sensor 20 is connected to the first input of the gas pressure control unit 22.5, the output of the gas temperature sensor 21 is connected to the first input of the gas temperature control unit 22.6, the output of the gas flow sensor 5 connected to the second inputs of the pressure control units 22.5 and gas temperature 22.6, the output of the temporary pulse generator 23 is connected to the third inputs of all control units 22.1 ... 22.6, the address output of the addressing unit 14 is connected to the fourth inputs of all the blocks Rola 22.1 ... 22.6, effluent output addressing unit 14 is connected to the fifth control inputs of all the blocks 22.1 ... 22.6, all control outputs blocks 22.1 ... 22.6 are connected to a corresponding input unit 16 poll the sensors.

The voltage sensors 1 and current 2 are designed to convert signals about the parameters of the electrical network into electrical signals that can be sensed by the input circuits of the converter 6; in the converter 6, the input signals about the current consumption and voltage form a product that is equal to the power that can be converted, for example, into the frequency of the pulses; sensors for hot water flow 3, cold water flow 4, gas flow 5 convert the physical flow parameter into an electrical signal, for example, a pulse frequency that can be sensed by the input circuits of the sensor polling unit 16 and the control units 22.1 ... 22.6;

- the control unit 7 performs general control of the system: calculates and stores the values of the consumed electricity, polls the sensor polling unit 16 about the state of the flow sensors of hot water 3, cold water 4 and gas 5, control units 22.1 ... 22.6 and remembers their values, performs the necessary calculation of the coefficients quality, issues all the necessary messages for display, interrogates the sensor unit 8 for displaying on the liquid crystal indicator 10 quantitative and qualitative indicators of the consumed utility services, it exchanges data with the addressing unit 14; control unit 7 can be implemented on the basis of a microprocessor or microcomputer (see Electronics, M .: Soviet Encyclopedia, 1991, pp. 301-303);

- block sensors 8 allows you to view the quantitative and qualitative indicators of all consumed utilities;

- the controller 9 provides image regeneration on the liquid crystal display 10;

- galvanic isolation blocks 11, 13, 15 are necessary to meet the requirements of electrical safety;

- the transmitting device 12 is necessary for the transfer of quantitative and qualitative indicators of all consumed utilities in the system of the highest level;

- the addressing unit 14 is necessary for addressing the control units 22.1 ... 22.6 in order to read information from them and generate a reset pulse for the control units, combining consumer systems into a higher-level system;

- the sensor interrogation unit 16 is necessary for counting pulses from the flow sensors of hot water 3, cold water 4, gas 5, converting them to obtain measurement units, receiving quality indicators from control units 22.1 ... 22.6, storing the results and transferring the results to the control unit 7 ;

- sensors for hot water pressure 17, hot water temperature 18, cold water pressure 19, gas 20, gas temperature 21 are necessary to convert physical parameters, such as pressure and temperature, into electrical signals that can be sensed by the input circuits of control units 22.1 ... 22.6;

- control units 22.1 ... 22.6 are made in accordance with the application for a patent of Ukraine No. a200612878 dated 12/06/06, the outputs of which are the outputs of the counters of the quality signals staying within certain limits and the total time of using the service for a certain period of time, for example, a month;

- the generator of temporary pulses 23 generates temporary pulses, which are perceived by the control units 22.1 ... 22.6 and fill in them the counters of the stay of quality signals within certain boundaries and the total time of use of the service for a certain period of time, for example a month.

The system operates as follows. At the first moment of the stipulated time, for example, at the beginning of each month, the control unit 7 stores the quantitative values of all services used for the last time they were used, from the control unit 7 through the galvanic isolation unit 13 and the addressing unit 14 to the fifth inputs of all control units 22.1 ... 22.6 a reset pulse arrives, which sets all the time counters of these blocks to "0".

The input voltage and current consumption values are supplied through voltage sensors 1 and current 2 to converter 6, where a product is formed that is equal to power and converted into an input signal for control unit 7, for example, to a pulse frequency, in which the pulses are converted to obtain electric units which are simultaneously transmitted to the transmitting device 12. The accumulated amount of energy used is stored in non-volatile memory and is simultaneously displayed on the screen Idcocrystalline indicator 10. In the polling unit of the sensors 16, pulses from the flow sensors of hot water 3, cold water 4, gas 5 are counted and recounted to obtain flow units of the corresponding service. At the request of the control unit 7, the flow rates of hot and cold water and gas are transmitted to the control unit 7 and stored in non-volatile memory.

After resetting the time counters in the control units 22.1 ... 22.6, in the time counters of the units, depending on the presence of the flow signal of the corresponding service, the accumulation of the residence time of the potential signals (voltage, pressure, temperature) in the corresponding sections of the ranges that characterize the quality of the service begins (see Decree of the Cabinet of Ministers of Ukraine No. 630 dated 07/21/05 "06 approving the Rules for the provision of district heating, cold and hot water supply and sanitation, and a model agreement for the provision of these services HS ", an application for a patent of Ukraine № a200612878 on 06.12.06).

After the stipulated time, for example, a month, in the control unit 7, the quantities of the used services for this month are calculated as the difference between the number of services used at the end of the month and at the beginning of the month, from the control unit 7 through the galvanic isolation unit 13 and the addressing unit 14 to the fourth inputs of all control units 22.1 ... 22.6 are received in turn addresses of the blocks and addresses of the counters of these control units. The numbers accumulated in the counters of the control units 22.1 ... 22.6, get through the block interrogation of the sensors 16 in the control unit 7, where they are used to calculate the quality factors according to the formula (1):

Where

K _to - quality factor;

T _s - the total time of use of the service for a specified period of time, for example a month;

T _i - the residence time of the quality signal on the i-th section of the range of variation of the quality signal for a specified period of time, for example a month;

K _i - coefficient for the signal, which is located on the i-th part of the range;

n is the number of sections over the entire range of the quality signal;

(see application for patent of Ukraine No. 200607592 dated 07.07.06).

The values of T _s and T _{i are} accumulated in the time counters of the control units 22.1 ... 22.6. The coefficients K _i and n are determined in regulatory documents. If K _{i is} considered a tariff coefficient, then in accordance with the Decree of the Cabinet of Ministers of Ukraine No. 630 of July 21, 2005, for n = 4 sections of hot water temperature, the tariff coefficients are equal to:

75 ° C-50 ° C K ₁ = 1; 49 ° C-45 ° C K ₂ = 0.9; 44 ° C-40 ° C K ₃ = 0.7; 39 ° C. - room K ₄ = 0.

For some services, there are two or more signals that determine the quality of the service. For example, for hot water, this is pressure and temperature. For such services, the quality factor is determined by the formula (2);

The amount of money paid for the used service is calculated in the control unit 7 according to the formula (3);

where О _p - the amount of payment for the used service;

T _tar - tariff for the service;

K _y - the number of services used for the current period of time, for example a month;

K _to is the quality factor of the used service for the current period of time, which is calculated according to formulas (1) or (2).

The proposed utility control system allows you to automatically determine the quantity and quality of utilities used, calculate the payment for utilities used in accordance with their quantity and quality in each individual apartment, and also allows you to control the conformity of the invoices sent by the manufacturer with the quantity and quality of each consumer .

Claims (1)

The utility control system, which consists of a voltage sensor, a current sensor, flow sensors for hot water, cold water and gas, a converter of consumption current and voltage signals to a power consumption signal, a control unit, a sensor unit, a controller, a liquid crystal indicator, a transmitting device, blocks galvanic isolation, addressing unit, sensor polling unit, and the outputs of the current and voltage sensors are connected to the inputs of the converter of the signals of the current consumption and voltage to the signal power output, the output of which and the output of the sensor unit are connected respectively to the first and second inputs of the control unit, to the third and fourth inputs and outputs of which are connected via the galvanic isolation blocks, respectively, the addressing unit and the sensor polling unit, the outputs of the hot flow sensors are connected to one of its inputs water, cold water, gas, while the first output of the control unit is connected to the input of the controller, the output of which is connected to the input of the liquid crystal indicator, the second output of the unit is controlled I am connected to the input of the galvanic isolation unit, the output of which is connected to the input of the transmitting device, the output of which is the output of the system, characterized in that it additionally includes a voltage control unit, a hot water pressure sensor and a hot water pressure control unit, a hot water temperature sensor and hot water temperature control unit, cold water pressure sensor and cold water pressure control unit, gas pressure sensor and gas pressure control unit, gas temperature sensor and temperature control unit gas generator, a temporary pulse generator, and the output of the voltage sensor is connected to the first input of the voltage control unit, to the second input of which a current sensor is connected, the output of the hot water pressure sensor is connected to the first input of the hot water pressure control unit, the output of the hot water temperature sensor is connected to the first the input of the hot water temperature control unit, the output of the hot water flow sensor is connected to the second inputs of the pressure and hot water temperature control units, the output of the cold water pressure sensor s is connected to the first input of the cold water pressure control unit, the second input of which is connected to the output of the cold water flow sensor, the output of the gas pressure sensor is connected to the first input of the gas pressure control unit, the output of the gas temperature sensor is connected to the first input of the gas temperature control unit, the sensor output the gas flow rate is connected to the second inputs of the pressure and gas temperature control units, the output of the temporary pulse generator is connected to the third inputs of all control units, the address output of the addressing unit is connected to the fourth inputs of all control units, the output of the addressing unit is connected to the fifth inputs of all control units, the outputs of all control units are connected to the corresponding input of the sensor interrogation unit.