RU2296305C1 - Method and integrated system for individual counting and adjustment of consumption of energy resources in housing and communal services - Google Patents

Abstract

FIELD: tool-making industry, in particular, systems for controlling measuring information by primary parameters, limiting consumption of communal services by tenants (hot and cold water, heat energy and electric energy, gas).

SUBSTANCE: for achieving result, thermostatic valves are mounted in each apartment for controlling heat mode, means for displaying information about amount of consumed energy resources and their costs. For measuring flow of gas and electric energy, electro-mechanical counters are sued with interface modules for transforming analog signals to digital signals. For measuring heat and water flow, used are, respectively, intellectual temperature transformation sensors and intellectual water amount transformation sensors.

EFFECT: increased precision of measurement, expanded functional capabilities.

2 cl, 2 dwg

Description

The invention relates to a metering tool for the consumption of utilities in housing and communal services, in particular to systems for generating, monitoring measurement information according to primary parameters determining tenants' utilization of utilities (hot and cold water, thermal energy and electricity, gas), and transmission it for processing in order to obtain the values (values) of actually consumed by consumers of energy resources according to the transmitted information and to monitor the health of system elements during operation tion and maintenance of residential buildings and settlements for utilities, and can be used in housing and communal services for all types of buildings and heat supply systems.

A known method of local control and accounting of heat consumption, described in the patent of the Russian Federation No. 2105958 in class. G 01 K 17/00, 17/08, c. 12/21/1995, on. 02/27/1998.

The known method consists in the fact that thermometric measurements are carried out in separate groups of heat-using installations at their input and output using thermal converters with different levels of supplied signals (by one degree of temperature difference), which are created proportional to the relative nominal thermal powers of the respective heat-using installations, ensuring the proportionality of the total signal level to the total consumption of thermal energy.

The disadvantage of this method is the not very high accuracy of the measurements, due to the fact that the measurement does not take into account the energy costs for heating common areas - stairways, staircase.

A known method of determining heat consumption by local consumers included in the integrated system of heat consumers, described in the patent of the Russian Federation No. 2138029 class. G 01 K 17/08, c. 06/09/1998, op. September 20, 1999

The known method is that the heat consumption is determined by the combined system of heat consumers for a specific heat transfer time by the heat source, the temperature difference on the surface of the heat source of the local heat consumer and the cooling medium of the local heat consumer is measured, the average heat transfer coefficient is determined by the combined system of heat consumers according to the formula:

α = Q / t × ΣS _i × ΔT _i ,

where α is the average heat transfer coefficient for the combined system of heat consumers;

Q is the heat consumption of the integrated consumer system for a specific heat transfer time by the heat source;

S _i is the surface area of the heat source of the local heat consumer;

ΔT _i is the temperature difference on the surface of the heat source of the local heat consumer and the cooling medium of the local heat consumer;

t is the heat transfer time by the heat source;

i = 1-n, where n is the number of local heat consumers,

then determine the heat consumption by the local heat consumer for the same specific time of heat transfer by the heat source according to the formula

Q _i = α × S _i × ΔT _i × t,

where Q _i is the heat consumption by a local consumer for a specific heat transfer time by a heat source.

The disadvantage of this method is the low accuracy of determining the consumption of energy, due to the fact that Q _i is actually a fraction of the consumption of thermal energy attributable to this apartment in the total house heat consumption, including heat spent on heating common areas. With this approach, when ΔT _i → 0, the amount of heat spent on heating common areas attributed to the ith apartment will also tend to zero, and the real value will be distributed between individual apartments. In addition, the consumer does not see how much heat is spent on heating his apartment, but how much is on heating common areas. Seeing only the total value of consumption, the consumer is weakly interested in saving heat.

A known system of network dispatch control, described in the article "From dispatching elevators - to the computerization of enterprises" in the journal "Housing and communal services", 2001, No. 6 p.16-20. The known system includes telemechanics complexes installed in each of the housing offices, and a network dispatch control system that integrates them, including the equipment of the facility: security alarm and diagnostics of elevators, pressure, flow, temperature sensors for monitoring the heating and water supply systems, actuators, and a central console in the form of a radio station at a control room connected to scheduling objects by wire or radio communication through appropriate modems.

A disadvantage of the known system is that it has limited operational capabilities in terms of energy saving, because It is mainly intended for monitoring and diagnostics of elevators and is quite expensive, as uses telecom complexes. Unfortunately, the article describes the system very briefly.

Closest to the technical nature of the claimed are the method and device for monitoring housing and communal information described in clause of the Russian Federation No. 2141626 "Device for monitoring housing and communal information" according to cl. G 01 F 1/00, A 62 C 2/00, G 08 B 17/00, c. 07/14/14., Op. November 20, 1999

The known method consists in the fact that in each apartment of residential buildings, counters or signal sensors are installed for each energy carrier consumed: gas, heat, hot and drinking water, electricity, take their readings and process information on energy carriers actually consumed by consumers: gas by its mass , heat, taking into account the main features of the heating system of the apartment, hot water by its energy content, electricity, taking into account changes in the temporary tariff, drinking water with temperature correction second error calculating consumption of each energy.

The disadvantage of this method is that it is not accurate enough, because it does not take into account the share of normative energy consumption in apartments that are not equipped with metering devices, common house heat losses taking into account "the participation of each apartment in common house losses and does not divide the total consumption into individual and common house parts . The device that implements this method comprises home controllers with storage devices containing house addresses, modems, a central control room electronic computer with a timer for storing events in time and a printer for providing legal paperwork and printing bill receipts payable by tenants, a personal computer with sound and light signaling, located in the security guard units, sensors of elevators operation parameters with help desks, cable, postal, telephone and / or radio communication channels, as well as unified sensors of electrical signals for temperature, pressure and volumetric flow rate of gas installed in apartments of residential buildings, sensors of electrical signals for temperature and volumetric flow rate of water, located at characteristic points of heating systems in apartments, drinking and hot water systems , 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 temperatures errors 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 panels, and also contains blocks of apartment meters of actually consumed gas by its mass, heat and electric energy, and drinking water and energy content of hot water, made in the form of electromechanical counters of electrical impulses corresponding to a given "unit" size spent energy with the possibility of their placement outside the apartments, while the sensors and call guards are connected via electronic converters to microcontrollers, which are connected to the blocks of apartment meters and to house controllers, connected via modems and communication channels to computers of the central control room and duty computers parts of the fire department, police, ambulance, gas emergency service, housing and communal services or elevator services located near the house, residents of which go need help. In the known system, the current housing and communal information is periodically periodically collected by a computer through modems, a telephone network, cable or radio channels from home microcontrollers. A person who needs help can press the call button for the appropriate help and the call signal interrupts the computer's data collection and enters through the computer of the central control room, where it is stored with the time stamp and address, to the nearest fire department, police, ambulance, emergency gas service, housing and communal services or elevator services. The main technical result of the known device is to increase the amount of information for analyzing the state of housing and communal services. A disadvantage of the known device is its limited operational capabilities, due to the use of analog circuitry and technical solutions that exclude the possibility of exchanging information of devices of various levels (apartment, house, system) and the possibility of implementing multi-tariff meters, which do not allow reducing consumer costs. In addition, the known device cannot be used in buildings with vertical wiring of heating systems.

In addition to the above, the known device does not provide the consumer with an accurate accounting of the energy resources consumed by him, since he does not divide the total consumption into individual (apartment) and communal parts.

The objective of the proposed method is to increase the accuracy of individual accounting of actual energy consumption for each apartment. The objective of the claimed system is to expand its operational capabilities while reducing consumer costs by providing more accurate individual metering and regulation of energy consumption.

The tasks are solved in that:

- in the method of individual metering and regulation of energy consumption in the housing and communal services, which consists in the fact that in each apartment of a residential building there are installed counters or signal sensors for each energy carrier consumed: gas, heat, hot and cold water, electricity, take their readings and they process information on energy carriers actually consumed by consumers, calculating the consumption of each energy carrier for a particular apartment, according to the invention, in each apartment additionally thermostatic valves for regulating the thermal regime and a means for displaying information on energy consumed in units of measurement and cost terms, for measuring gas and electricity consumption, use electromechanical meters with interface modules for converting discrete pulse signals to digital, for measuring heat and water consumption use smart temperature conversion sensors and smart quantity conversion sensors respectively water or electromechanical water meters with interface modules, measure with their help the temperature and amount of water directly on risers in the apartment and in the entrance and determine the actual heat consumption in a separate apartment, based on the calculation of the heat balance according to the principle of equality of the heat consumption measured by the heat meter throughout home and the consumption of thermal energy received for heating individual apartments, according to the formula:

Q _house = ΣQ _iind + ΣQ _norms + Q _generally ,

where Q _iind is the heat consumption for heating of each apartment according to the readings of intelligent temperature conversion sensors and riser intelligent sensors for the amount of hot and cold water;

- Q _norms - the share of the normative consumption of thermal energy by a separate apartment;

- Q by _common - the amount of heat spent for common purposes, defined as:

Q by _{common house} = Q _house -ΣQ _iind -ΣQ _norms

at the same time, the "participation" of each apartment in the consumption of heat spent for communal purposes is determined by the formula:

Q by the _general = δ _i × Q by the _general

where δ _i - the "weight" coefficient of a particular apartment, defined as δ _i = S _i / S _accounting , where

S _i - the area of a separate apartment;

S _metering is the area of apartments equipped with meters, and as a result, the actual heat consumption for a separate apartment equipped with metering devices is calculated, as

Q _i = Q _iind + Q _i

Where Q _iind. - heat consumption for heating the apartment directly according to the testimony of apartment intelligent temperature conversion sensors and riser intelligent sensors for converting the quantity,

Q _{i general} - the consumption of each apartment for heating a common area (common house losses),

then, using the display means, they provide each consumer with information about the energy resources consumed by his apartment and their cost for monitoring and regulating, if necessary, the consumption of thermal energy through thermostatic valves;

- in an integrated system of individual metering and regulation of energy consumption in housing and communal services, including temperature, gas, electricity and water sensors installed in apartments of residential buildings, made in the form of electromechanical electric pulse counters corresponding to specified “unit” sizes of energy consumed, and located at characteristic points of the heating systems of apartments, cold and hot water supply systems, local concentrators made with the ability to memorize apartment numbers and collect data on gas, electricity, drinking water consumption, hot water energy and store these values for the time when there is no power supply, equipped with autonomous power supplies, electronic converter units with network power supplies, as well as home hubs with storage devices containing the addresses of houses, modems, an electronic computer of the central control room with a timer for remembering events in time A printer and to provide a printout of certificates of actually consumed energy resources, while the sensors are connected to local concentrators, which are connected to house concentrators, connected via modems and communication channels to computers of the central control center of the housing and communal services, according to the invention, the apartment equipment additionally contains wired or wireless apartment monitors for displaying information on consumed energy resources in physical and cost units and health of elem system sensors, and as sensors for temperature and water flow, intelligent temperature conversion sensors and intelligent sensors for converting the amount of hot and cold water or electromechanical water meters with a pulse output in conjunction with interface modules are used, respectively designed to account for individual consumption of heat and hot and cold water moreover, intelligent sensors of temperature, the amount of hot and cold water are connected to local concentrators directly Actually, while gas, electricity and water meters are connected to local concentrators using interface modules used to convert pulse signals to digital, the system also includes individual thermostatic valves to maintain optimal thermal conditions in a separate apartment and a house heat meter installed in an individual heat a point for metering energy resources, while local hubs serve as devices for collecting information from smart sensors, connected by Ohm of the apartment bus with sensors, using interface modules - with meters, via a bus or a radio channel connected to the apartment monitors and through the house bus with a house concentrator, which is also a device for collecting information from local concentrators and from a house heat meter and connected to the central control center through a wireless or wired communication channel, while the computer of the central control center performs the function of scheduling the number of services consumed for each quarter Monitoring and fault monitoring and computing devices for transmitting the necessary information.

In the inventive method, the installation in each apartment of thermostatic valves for regulating the thermal regime and means for displaying information about the consumed energy resources in their actual volume and cost terms and using electromechanical meters with interface modules or smart meters as gas, electricity, heat, hot and cold water meters sensors for measuring the temperature and quantity of water, together with the choice as the basis for calculating the principle of equality of heat consumption, measured about the whole house with the help of a home heat meter, and the heat consumed by each apartment, provided that it is measured directly on the risers in the apartment and when determining the house expenses, the share of normative heat consumption, as well as the share of heat spent for common house purposes and measured on risers in the entrance, using the "weight" coefficients of individual apartments allows you to take into account all the actual costs of each local consumer, providing a more accurate calculation of heat consumed, and reduce consumer costs due to providing the ability to control and regulate their consumption.

The technical result is an increase in the accuracy of determining consumption by dividing the total consumption into individual (apartment) and communal parts and reducing the cost of energy consumption by the consumer due to the possibility of controlling and regulating consumption.

In the claimed system, the introduction into the apartment equipment of smart sensors for monitoring the parameters of heat and water supply systems, as well as apartment monitors and local concentrators, representing data collection devices with memory elements that allow collecting, displaying and controlling information on energy consumption in each apartment and house, when used to optimize the heat consumption of the home heat meter of an individual heating unit, it provides the ability to exchange information on different Sheep - apartment, house and system, allows the consumer to allocate an individual (apartment) and common house share of energy consumption, and in conjunction with the installation of thermostatic valves in apartments - to regulate and optimize the heat supply mode, which together with the use of a computer at the central control center to perform identification functions objects of observation, storing energy consumption data and calculating the cost of energy consumed allows you to expand operation In system capabilities, more accurate account of individual consumption of energy resources and reduce consumer expenditures on housing and communal services. EFFECT: increased accuracy of accounting of consumed energy resources and providing the possibility of individual monitoring and regulation of energy consumption in real time. The inventive method of individual metering and regulation of energy consumption in housing and communal services has a novelty in comparison with the prototype, differing from it by the presence of such essential features as the installation of thermostatic valves in each apartment to regulate the thermal regime and means of displaying information about energy resources consumed and their cost, use as meters and sensors of electromechanical meters with interface modules or smart sensors for measuring the temperature and amount of water (ISPT and ISPK), the determination of individual heat consumption according to the testimony of ISPT and ISPK directly on risers, based on the calculation of the heat balance according to the principle of equality of the heat consumption measured throughout the house with the use of a common house heat meter and the heat energy consumed for heating of individual apartments as the sum of the measured individual consumption for all apartments of the house, the share of standard heat consumption by non-equipped means of metering apartments and general house heating costs eating common use, by the surface area of the flat, providing improved accuracy in conjunction every apartment calculate the actual heat consumption and cost reduction of the consumer due to receipt of the required information by means of its display capabilities and consumption regulation through thermostatic valves.

Compared with the prototype, the claimed system has novelty, differing from it by the presence of such essential features as the introduction of smart sensors into the equipment of apartments to monitor the parameters of heat and water supply systems, apartment monitors and local concentrators, as well as a house concentrator, which are collection devices and displaying information about consumed energy resources, and using an individual heat station to optimize the heat and water consumption of a house heat meter and and thermostatic radiator valves in the apartments for the optimization of heat and water regimes, the use of computers as a central control means. The applicant is not aware of technical solutions that have the indicated distinctive essential features, which together ensure the achievement of a given result, therefore, he believes that the claimed method and integrated system for its implementation meet the criterion of "inventive step".

The inventive method and system can be widely used in utilities, and therefore meets the criterion of "industrial applicability".

The claimed invention is illustrated by drawings, which are shown respectively in:

figure 1 - functional diagram of the system;

figure 2 is a functional diagram of a local hub.

The inventive method is as follows. In each apartment, thermostatic valves are installed to regulate the thermal regime, means for displaying information on the amount of energy consumed and their cost; to measure gas and electricity consumption, electromechanical meters with interface modules are used to convert analog signals to digital. To measure heat and water flow, respectively, intelligent temperature conversion sensors (ISPT) and intelligent water quantity conversion sensors (ISPK) or electromechanical water meters with interface modules are used, they measure the temperature and amount of water directly on risers in the apartment and in the entrance. Measured with a general building heat meter heat flow Q _house around the house. The actual heat consumption Q _{i ind} for a separate apartment is determined based on the calculation of the heat balance on the basis of the equality of the heat consumption measured by the heat meter throughout the house and the heat consumption received for heating individual apartments, according to the formula

Q _house = ΣQ _iind + ΣQ _norms + Q _generally ,

Where Q _iind is the actual heat consumption for heating of each apartment according to the testimony of ISPT and riser ISPK

- _Qinorm - the amount of heat calculated according to the standard for each of the apartments not equipped with metering devices;

- Q by _{common house} - the amount of heat spent for general house purposes.

Household heat loss is defined as

Q by _{common house} = Q _house -ΣQ _iind -ΣQ _iinorm .

Take into account the "participation" of each apartment in the general house heat loss in the amount of Q by the _general = δ _i × Q by the _general where δ _i is the "weight" coefficient of a particular apartment, defined as

δ _i = S _i / S _accounting ,

where S _i - the area of a separate apartment;

S accounting - the area of apartments equipped with meters.

The total actual heat consumption for a separate apartment is calculated as Q _i = Q _iind + Q _{i communal} , where

Q _iind - heat consumption for a separate apartment by the meter,

Q _{i general} - the consumption of each apartment for heating a common area (common house losses).

Using the means of information display, they provide each consumer with information about the energy resources consumed by his apartment and their cost, so that the consumer can control the consumption of energy resources and, if necessary, adjust it using thermostatic valves. The inventive method is as follows.

Each apartment is equipped with thermostatic valves, a means of displaying information, electromechanical meters of gas, electricity, equipped with interface modules, intelligent sensors for converting temperature and quantity of water, or electromechanical meters of temperature and amount of water, equipped with interface modules. The latter are also installed in the entrance to the risers. The house is equipped with a common house heat meter.

The initial value for the calculation is the readings Q _{house of the} general heat meter (house heat meter), which records the heat consumption for heating in the building, expressed in Gcal. For cases of the presence of residential and non-residential premises of the building that are not involved in the general settlement system (non-residential additions to the building and (or) use for non-residential purposes of the basement of the building, apartments whose owners refused to pay for installation and maintenance of ISIURE), first from the readings of the general heat meter Q _house. The consumption of heat Q _norms in these rooms is deducted. These data for individual rooms are determined according to the approved standards for residential premises or in another calculation way as ΣQ _standards .

Based on the calculation of the heat balance, the total amount of the calculated values of the thermal energy for heating for all consumers of the unit of account must be equal to the thermal energy measured by the common house heat meter for heating.

The estimated amount of thermal energy consumed by the apartment for heating is equal to the sum of the individual part of the heat energy consumption of the apartment and the common house part.

Next, the individual part of the expenditure of thermal energy for heating each consumer in the unit of account is determined.

The individual parts of the heat energy spent on heating each apartment equipped with individual metering devices can be multiplied by the individual decreasing coefficient of the apartment’s location, taking into account the unfavorable location of the apartment in the building in terms of heat loss (apartments on the first and last floors, corner apartments).

In each building there are constant common building charges of heating energy for heating, which individual consumers cannot influence. Fixed utility costs Q are _generally defined as the difference in the readings Q _{house of the building} energy meter for heating, total Q _iind. individual costs of thermal energy for heating in all apartments of the unit of account and the amount of costs ΣQ _inorm . For apartments not equipped with accounting facilities (Q _general = Q _house -ΣQ _iind -ΣQ _iNorm. ).

The values of the general house-hold expenses (costs) of thermal energy should be distributed among all the apartments of the settlement unit equipped with metering devices, by means of “weight” coefficients. The weighting coefficient, taking into account the share of each (i-th) apartment in the total house heat energy consumption, is calculated depending on the area occupied by the apartment as:

δ = S _i / S _accounting ,

where S _i is the floor area of the i-th apartment, m ² ;

S _accounting - floor area of all apartments of the accounting unit equipped with accounting facilities.

Then the share of the i-th apartment participating in the accounting system in the general cost of heat energy is determined as,

Q _i . _General = δ × Q _i . _General .

The total actual heat consumption for a separate apartment equipped with individual metering is

Q _i = Q _i.ind + Q _i .

The consumer can control the consumption of energy resources by his apartment using the means of displaying information installed in each apartment and, if necessary, regulate this consumption by means of thermostatic valves.

The inventive system (Fig. 1), with which the inventive method is implemented, comprises installed (apartment) electricity meters 1, gas meters 2, water meters 3, interface modules 4, smart sensors 5 for temperature conversion for monitoring the heat consumption of apartments, smart sensors 6 hot and cold water, thermostatic valves (not indicated and not shown in the drawings), as well as local concentrators 7 (figure 2) for collecting and processing information, each of which contains a processor 8, ele ment 9 memory and a power source 10 (mains or battery) and is equipped with interfaces 11 for communication with apartment monitors 12, home concentrator 13 and with the mentioned counters 1, 2, 3 and sensors 5, 6. Counters 1, 2, 3 are also equipped interface modules 4 for signal conversion. The system also includes a set of 14 equipment for common-house commercial metering of heat and water consumption installed in the house, including a heat meter 15, and a set of equipment, which is an individual heat point 16. The heat meter 15 is connected to a house concentrator 13 connected through a modem 17 and a communication channel 18 with a central control room 19. The central control room (DAC) 19 contains a computer that serves to identify the controlled object, store an archive of data on energy consumption ah, the printout of receipts for payment and payment monitoring. The purpose and implementation of nodes and elements is as follows. Electric meters 1, gas meters 2 and water meters 3 are used to measure the flow of electricity, gas and water and are standard meters with a pulse output signal and are equipped with interface modules 4 for signal conversion. Intelligent temperature conversion sensor 5 (ISPT) is used to directly measure the thermal energy of an apartment consumed by each apartment, and contains a heat-sensitive element and an electronic signal conversion unit.

Intelligent sensor 6 converting the amount of water (ISPK) is used to determine the volume of water consumed and contains a wing meter for the amount of water and an integrated interface module for converting the signal.

Water metering can also be carried out using standard water meters with a pulse output and an interface module. Thermostatic valves are used to regulate the individual consumption of thermal energy.

The local concentrator (LK) 7 (apartment or driveway) is designed to collect data from individual metering devices, transfer them to the house concentrator and to the apartment monitor. It can be used as both an apartment and a riser. The local hub 7 (see Fig. 2) contains a processor 8, a memory element 9, a power source 10 and interfaces 11 ', 11' 'and 11' '' for communication with sensors 5, 6 and counters 1-3, respectively, through interface modules 4, the home hub 13 and the monitor 12. Moreover, with the sensors 5 and 6 and the counters 1-3, the local hub 7 is connected using the apartment bus 20 (see figure 1). Monitor 12 is autonomous, and has the ability to connect to a local hub 7 via a wireless or wired communication channel via an apartment bus.

The house concentrator (DK) 13 serves to collect information from local concentrators (apartment and riser), its further processing into the actual values of the energy parameters of individual metering. The home hub 13 is made on the controller 21 (for example, I-7188XAD) and is equipped with a modem 17 (in particular, of the Zyxel 336 type) for communication via a wired (dedicated channel or telephone line) or wireless (radio or mobile telephone) communication channel 18 with Central Dispatch Station 19. (system level).

The individual heat point (ITP) 14 serves to optimize the regime of heat supply and hot water supply with economical consumption of energy resources, as well as commercial metering of heat energy. A heat meter has been installed at an individual heat point 14, which is made in accordance with GOST R51649 and serves to account for the parameters of the house-wide consumption. Dispatch point 19 (system-wide level) contains a computer 22 with a printer (not shown in the drawing) and is connected through a modem 23 to a house hub 13. It serves to dispatch data on resources consumed by tenants and houses completely, store hourly, daily and monthly consumption archives, updating, if necessary, the contents of the archive with the contents of home concentrators, printing receipts for energy consumption and monitoring failures of system elements. The control room 19 is also connected to the database server 24, which is not part of the system and serves to exchange data with the city’s service departments.

Using the inventive system (figure 1), the inventive method is implemented as follows.

Signals from smart sensors 5 for temperature conversion (ISPT) and sensors 6 for quantity (ISPK) of hot and cold water, as well as from counters 1-3 of electricity, gas and water through interface modules 4, are collected by local concentrators 7 from apartments and heating risers for their further transmission to the home concentrator (DK) 13. In case of loss of communication with the home concentrator 13, each local hub 7 continues to poll connected devices and, when communication is restored, transfers them to the home concentrator 13. Discreteness of interrogation of appliances the apartment level can be adjusted from 5 minutes to 1 hour. Data from counters 1-3 and ISPK 6 are considered cumulative and the final value for each parameter is transmitted to DC 13. When forming an array of measured parameters, the local concentrator 7 forms a single time array, consistent with DC 13.

The local hub 7 (figure 2) is powered from a power source 10 - 220 V network or from a battery. The number of connected apartment and riser devices is up to 32. The input interface is from the HART / RS 485 apartment devices, the exchange rate is 9600 baud. To present data to the tenant, a monitor 12 is used (see Fig. 1), to which the local (apartment) hub 7 provides the following reporting information from the beginning of the current accumulation month and archives for the previous months according to the following parameters:

- heat;

- HVS;

- DHW;

- electricity;

- gas;

- the common house component of the above parameters.

The local hub 7 stores in the memory element 9 the monthly archives of the aforementioned consumed parameters for the last 18 months. Archives and the accumulated consumption value from the beginning of the month are available for viewing by the tenant on the monitor indicator 12. The parameters are transferred in one transaction and stored in the volatile memory of the monitor 12. With each survey of apartment and riser devices, the local hub 7 diagnoses the connection with them. In the case of loss of communication with any of the sensors, the local hub 7 activates the flag of loss of communication with the device in the frame of exchange with DC 13.

Upon request from the home hub 13, the local hub 7 provides a unique identifier for the “lost” device. The local hub 7 has an external indication on the monitor 12:

- indication of the penalty mode;

- indication of the breakage of any apartment or riser device;

- Indication of loss of communication with the home concentrator;

- indication of mains power and batteries.

The local hub 7 has the ability to configure parameters through the RS485 port.

The house concentrator 13 collects information from local concentrators 7 (apartment and riser), then processes it into the actual values of the energy parameters of the individual metering. Based on the data received from the apartment local concentrators 7, he calculates the thermal energy directly consumed by each apartment, and its monetary equivalent, recalculates the consumption of water, gas and electricity from the beginning of the month and transfers this information to the apartment local concentrators 7 for display on monitors 12 House Hub 13 maintains monthly archives up to 18 months deep, per diem archives up to 45 days, sentinel archives - 5 days. Based on the data of the home heat metering unit, the home concentrator 13 calculates the heat energy consumed by each apartment and its monetary equivalent. This parameter has two components: the energy directly consumed by the apartment, and the share of each apartment in communal consumption. The share of direct consumption is calculated according to the ISPT 5 and the corresponding riser ISPK 6. The determination of the part of house-wide losses for each apartment in the house-wide consumption of thermal energy is directly proportional to the area of the apartment. At the same time, it is possible to introduce correction factors for the location of the apartment in the house.

When determining a part of the common house losses of hot water and hot water for each apartment, the value of individual consumption is taken as the basis for the readings of apartment water meters. The house concentrator 13 archives in its memory information on individually consumed energy resources, and also transfers it to the central control center 19 of the district. No more than 128 local hubs 7 can be connected to home hub 13. The exchange protocol with local hub 7 is RS485 / HART, the exchange rate is 19,200 baud. DK 13 has an RS232 output for connecting a transmitting modem 17. The exchange protocol is standard and open, used in tasks of this class. Communication with the heat meter 15 is carried out via the RS 485 / HART interface. DK 13 archives each parameter (domestic hot water, cold water, heat) according to the individual consumed component and the component of common house losses separately, and for gas and electricity only according to individual consumption. The archive in rubles is stored in the memory of DK 13 permanently and is calculated on the basis of an archive of data on energy consumption in physical units and current tariffs.

In the apartment local concentrators 7, the house concentrator 13 returns information by the accumulated total from the beginning of the month for all of the above parameters. At the end of the month, DC 13 generates a monthly archive of consumed energy resources and transfers it to the local hub 7.

With the central control room 19, the home concentrator 13 exchanges information once a day and transmits a daily archive of consumed resources in physical units. The cash equivalent is calculated in the computer of the control room 19 based on current tariffs. Each parameter breaks down into individually consumed resources and a share in the total amount of resources spent for communal purposes. The list of parameters sent to the central control room 17:

- unique identifier (house number, street code, apartment number);

- DHW (consumption);

- HVS (consumption);

- electricity (consumption);

- gas (consumption).

The central control room 19 maintains an annual report of monthly archives of consumed resources for each apartment, taking into account general house losses, and can update the contents of the archive, both current and annual, with the contents of house concentrators. In case of discrepancy between the contents of the archives from the recreation center 13 and the dispatching system, the value of the central control room is taken as the correct one and the corresponding value is recorded in the house concentrator 13. The central control room 19 prints out receipts for actually consumed energy resources for the current month, as well as print archives using a printing device for any period of the system’s operation.

According to the current indications of ITP 15, DK 13 or TsDL 19, it is possible to regulate heating, cooling and domestic water supply systems using actuators, such as a device for hydraulic adjustment and balancing, riser regulating equipment for heating and hot water supply (balancing valves). According to the indications of the apartment monitor 12, the tenant can regulate the individual consumption of thermal energy and water using thermostatic radiator and hydraulic valves.

Compared with the prototype, the inventive method allows more accurately take into account individual energy consumption, and the integrated system of individual metering and regulation of energy consumption in the housing and communal services has wider operational capabilities while reducing consumer costs by improving the accuracy of individual metering of energy resources.

Claims (2)

1. The method of individual metering and regulation of energy consumption in the housing and communal services, which consists in the fact that in each apartment of a residential building, counters or signal sensors are installed for each energy source consumed: gas, heat, hot and cold water, electricity, take their readings and they process information on energy carriers actually consumed by consumers, calculating the consumption of each energy carrier for a particular apartment, characterized in that I install in each apartment in addition, thermostatic valves for regulating the thermal regime and a means of displaying information on energy consumed in units of measurement and in cost terms, for measuring gas and electricity consumption, use electromechanical meters with interface modules for converting analog signals to digital, for measuring heat and water consumption, respectively smart sensors for converting temperature and smart sensors for converting the amount of water or electric mechanical water meters with interface modules, measure with their help the temperature and amount of water directly on risers in the apartment and in the stairwell, measure the heat consumption throughout the house using a common house heat meter and determine the actual heat consumption for a separate apartment, based on the calculation of heat balance according to the principle the equality of the heat consumption measured by the common-house heat meter throughout the house and the consumption of thermal energy received for heating individual apartments, according to the formula Q _house = ΣQ _iind + ΣQ _norms + Q _generally , where Q _iind is the actual heat consumption for heating each apartment according to the readings of intelligent temperature conversion sensors and riser intelligent sensors for converting the amount of hot water; _Qinorm - the amount of heat calculated according to the standard for each of the apartments that are not equipped with individual metering; Q by _common - the amount of heat spent for common purposes, defined as Q by _{common house} = Q _house -ΣQ _iind -ΣQ _norms , taking into account the "participation" of each apartment in the total consumption of heat in the amount Qi by _public = δ _i × Q by _public , where δ _i - "weight" coefficient of a particular apartment, defined as δ _i = S _i / S _accounting , where S _i - the area of a separate apartment; S _accounting - the area of apartments equipped with meters, and as a result, the actual heat consumption for a separate apartment is calculated as Q _i = Q _iind + Q _i where Q _iind is the heat consumption for a separate apartment according to the testimony of intelligent temperature conversion sensors and riser intelligent sensors for converting the amount of hot water; Q _{i general} - the consumption of each apartment for heating a common area (general house expenses), then, using the display means, they provide each consumer with information about the energy resources consumed by his apartment and their cost for monitoring and regulating their consumption with thermostatic valves. 2. An integrated system of individual metering and regulation of energy consumption in the housing and communal services, including temperature, gas, electricity and water sensors installed in apartments of residential buildings, made in the form of electromechanical electric pulse counters corresponding to specified “single” sizes of energy consumed, and located at the characteristic points of the heating systems of apartments, cold and hot water supply systems, local concentrators made with the ability to memorize apartment numbers and collect data on gas, electricity and water consumption, energy content of hot water and memorize these values during the absence of mains power, equipped with autonomous power supplies, electronic converter units with network power supplies, as well as home hubs with storage devices containing addresses of houses, modems, an electronic computer of the central control room with a timer for storing events in time and a printer for I provide printouts of certificates of actually consumed energy resources, while the sensors are connected to local concentrators, which are connected to meters and to house concentrators, connected via modems and communication channels to computers of the central control center of the housing and communal services, characterized in that the apartment equipment additionally contains wired or wireless apartment monitors for displaying information on consumed energy resources in physical and cost units and health of elements system, and as sensors for temperature and water flow, intelligent temperature conversion sensors and intelligent sensors for converting the amount of hot and cold water or standard water meters with a pulse output in conjunction with interface modules are used, respectively designed to account for individual consumption of heat and hot and cold water moreover, intelligent sensors for converting temperature and the amount of hot and cold water are connected to local concentrators mediocre, and gas, electricity and water meters are connected to them using interface modules used to convert pulse signals to digital, the system also includes individual thermostatic valves to maintain optimal thermal conditions in a separate apartment, a house heat meter installed in an individual heat point for energy accounting, while local hubs serve as devices for collecting information from smart sensors, connected via apartment buses with sensors and interface modules with meters and connected via a bus or a radio channel to apartment monitors and via a house bus with a house concentrator, which is also a device for collecting information from local concentrators and from a house heat meter and connected to the central control center via a wireless or wired channel communication, while the computer of the central control room performs the functions of dispatching the number of consumed services for each apartment and monitoring spravnostey computing device and to transmit the information required.

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