RU6890U1 - HEAT APARTMENT SYSTEM - Google Patents

Abstract

1. The apartment heat metering system for a one-pipe heating system, including group heat meters for measuring the amount of heat consumed by a group of apartments from each access riser of heating water with means for measuring spilled volume V of input and temperature difference ΔT of temperatures in the supply and return branches of the riser and calculators for calculating the amount of heat from interface units for transmitting measurement information over communication lines, information processing devices installed on a group of heat meters for amounts the amount of heat consumed by the group of apartments from all risers of the entrance, the interface inputs of which through the first communication lines are connected to heat meters, and their interface outputs through the second communication lines are connected to an electronic computer, characterized in that for calculating the share of each apartment in the heat of each access riser, it is supplemented by temperature converters installed in each apartment for each access riser when they enter the apartment in the area of the interfloor Events, the outputs of which through third communication lines are connected to information processing devices, in which the share in the heat consumption of the k-th apartment from the i-th access riser is calculated in accordance with the formula where ΔT is the floor difference in temperature for the k-th apartment in the i-th riser, and the total amount of heat consumed by the k-th apartment from all the risers of the staircase brought to it is determined by the expression where m is the number of access risers brought to the k-th apartment. 2. The accounting system according to claim 1, characterized in that the algorithm for calculating heat consumption

Description

HEAT APARTMENT SYSTEM

The invention relates to information-measuring systems and can be used in housing and communal services for the commercial accounting of the amount of heat released for space heating.

The Pollu Data Bus System by SPANNER POLLUX, Germany, is known for accounting for heat in rooms in which the boundary of the balance section is an apartment (see the SPANNER POLLUX catalog, Appendix 1). The system contains heat meters based on at least one per apartment, combined into a system for collecting and processing information, each of which consists of means for measuring the volume and temperature of heating water coming from the entrance supply riser to the apartment and returned to the return riser, and calculators consisting of mathematical processing units, in which the heat consumed for heating is defined as the product of the difference in water temperatures in the supply and return pipelines and the spilled volume, and interface units for transmitting measuring information, processing devices installed on

a group of heat meters, for example, to the entrance of a building, which sums up the heat consumed within each apartment, if it is heated from several access risers and calculates the average monthly consumption, as well as a personal computer connected to communication line processing devices and designed for documentation measuring information in the generally accepted form. The disadvantages of the known device include its high cost. In the framework of the known device within each apartment, expensive means of measuring volume are used. Depending on the project of the residential building and the size of the apartment, its heating can and, as a rule, is carried out from several access risers, which forces the circulation of volume measuring instruments even within the same apartment.

Also known is a system for housing metering of heat, which has become widespread in the Baltic states (see the newspaper Izvestia Nza

1997 Appendix 2). It contains group heat meters installed on the basis of one or several (according to the number of access risers of heating water) per group of apartments, for example, located in one entrance, also containing means for measuring the volume and temperature difference} / p in the supply and return pipelines, and quantity calculators heat released in each riser, processing devices installed, for example, according to the number of building entrances that sum the released heat within the building entrance and transmit using measurement lines nuyu information in personal computers, the latter calculates the heat allotted to each apartment on basis of its share of proportional area of each apartment.

The disadvantages of the known device include low accuracy of measurement, caused by the fact that the area of the apartment does not reflect its design spatial orientation in the building, the degree of insulation, number of storeys and associated temperature of the heating water in the riser, etc. The known device does not stimulate energy saving.

Closest to the claimed in its technical essence is the system of the company Raab Karcher Ene.groservice, Denmark (see Appendix 3). It contains group heat meters installed at the rate of one or several per group of apartments, for example, in one entrance, of evaporative type installed on each heat-generating device (water heating radiator) within each apartment to determine its share in the heat consumption within each entrance, measuring information processing devices for calculating the heat consumed by each apartment, communication lines and a personal computer for documenting in a common way e.

The disadvantages of the known device include the high cost and low accuracy of the measurement, since the number of evaporative type instances in each apartment should be determined by the number of water heating radiators, and the instances themselves can be unintentionally or deliberately shielded from evaporation by the residents of the apartment, which can distort the measurement information by several time.

The purpose of the claimed utility model is to reduce the cost by reducing the number of measuring instruments and increasing accuracy. By reliably determining the share of each apartment in heat consumption.

This goal is achieved by the fact that to calculate the share of each apartment in the heat removal from each access riser, the apartment heat metering system is supplemented by temperature converters installed in each apartment for each access riser when they enter the apartment in the area of the floor, the exits of which are through third lines communications are connected to information processing devices in which the share in the heat consumption of the apartment from the i-oro access riser is calculated in accordance with the formula th: G .1 where .i is a floor

riser

and the total amount of heat consumed by the k-th apartment from all the risers of the staircase brought to it is determined by the expression:

Gk-s

where t is the number of access risers brought to the k-th apartment.

In FIG. 1 is a block diagram of an apartment heat metering system, and FIG. 2 - a variant of its execution in the case of using quartz temperature transducers.

The apartment heat metering system contains group heat meters 1, 1, etc., installed in the entrances of buildings at the rate of one to the riser of the heating water of a one-pipe heating system and connected to the supply and return pipelines. Each heat meter contains one means 2 for measuring the volume in the i-th riser of the building and two means 3 for measuring temperature in the supply and return pipelines. Each group heat meter 1 (1; 1, etc.) contains a calculator 4 (4; 4, etc.) with an interface unit connected via the first communication lines 5 to the inputs of devices 6 (6; 6 and t) .d.) processing of measurement information, also containing interface units, the outputs of which are connected to the electronic computer 8 through the second communication lines 7.

In each apartment receiving heat supply from one or several access risers of heating water, temperature converters 9 are connected at their points to the apartment at the floor level, the interface outputs of which are combined and connected to the inputs of devices 6 (6; 6 and 6 using the third communication lines 10) etc.) processing of measurement information. U I Kt X) the temperature difference for the k-th apartment in the i-th b. The system operates as follows. Group heat meters 1 (1; 1, etc.) calculate the heat consumed by a group of entrance apartments each from its own riser of heating water, measuring the amount of water spilled through the riser, using means 2 (2; 2, etc.) of measurement volume, for example, of a vane or ultrasonic water meter, and water temperature in the supply and treatment pipelines using group converters 3 (3; 3, etc.) of temperature. At the same time, it is understood that the volumes of spilled water through the water heating radiators of all apartments connected to one riser are the same and equal to Vf, and the temperatures at the entrance to the entrance and exit in the supply and return pipelines, respectively, characterize their total heat consumption. Calculators 4 (4; 4, etc.) of heat meters 1 (1; 1, etc.) calculate the heat G- released to the group of entrance apartments within the i-oro riser according to the well-known algorithm: & с c (r.-7 -.,. where: i in iO is the group temperature difference determined by the calculator Using their interface unit and the first 5 (5; 5, etc.) communication lines, the heat meter calculators inform devices 6 (6; 6, etc.) ) processing of calculated heat at the request of the latter, for example, once per hour.In each apartment, only individual means of measuring temperature 9 are installed, and their number corresponds to the number of access risers involved in heating a particular apartment.Temperature measuring instruments 9, for example, based on platinum or copper resistance thermometers, are installed at the entrance of each access riser a, to a specific apartment in the area of the floor and control the temperature distribution along the length of the riser within its ascending and descending branches.Transmitters 9 are equipped with interface units and are connected to devices 6 (6; 6, etc.) treatments that periodically, for example, once every 10 minutes, interrogate them, inquiring about the temperature distribution along the length of the i-oro riser, and, based on the results of the polls, calculators determine the hourly average temperature distribution. , To each apartment of the entrance connected to the i-th riser, there is set, in accordance with the interfloor temperature difference, defined as the difference in the hourly average values between the temperature in the apartment in question and the temperature in the apartment located higher on the floor in the ascending branch

riser or temperature in the apartment in question and in the apartment on the floor below in the descending branch of the riser.

Moreover, in composite group heat meters, temperature converters 9 of the first and last apartments along the riser can be used as group temperature measuring devices 3, respectively, to measure temperatures in the supply and return pipelines.

The temperature differences determined by devices 6 (6; 6, etc.) for processing the temperature difference characterize the share of each apartment in the heat removal from the i-th riser.

Group heat meters, upon request, inform device 6 of the hourly average value of the heat G-i consumed by the group of apartments from the i-oro riser and the difference in dT, temperatures in the supply and return pipelines. Device 6, receiving information about the average hourly interfloor temperature difference, calculates the average hourly heat consumption of the k-th apartment in accordance with the expression:

G-. DP (1)

In addition, the device 6 performs the summation of the hourly fraction of the thermal energy received by the k-th apartment from m risers suitable to it.

  S (2)

Upon request from the electronic computer 8 on the second communication lines 7, the hourly average values of the heat consumed by each of the apartments covered by the system are supplied to it. Computing machine 8 determines the average monthly heat consumption of each apartment, archiving these values, for example, during the year and at the initiative of the operator, carries out documentation (printing) in a generally accepted form.

In the claimed device, the heat released to the group of apartments of the entrance is calculated from the head gate valves of the risers. If we neglect the losses in the sections of risers from the head valve to the first apartment along its course and from the last apartment to the head valve in the descending branch, then the heat calculation algorithm can be greatly simplified. In this case, the group heat meter measures the volume of / 1 spilled through the i-th riser, requests the interfloor temperature difference DT, 1 for all apartments connected to the i-th riser, and calculates the heat released in accordance with the formula:

cc ,,

in the future, the system is similar to the above.

The use as individual means 9 of measuring the temperature of quartz thermometers with selected characteristics within the same riser allows you to simplify their interface. In this case, a quartz thermometer 9 (see Fig. 2), consisting of a sensing element 11, a generator 12 with a characteristic linearizer is supplemented by a frequency comparator 13, and the reference input of the comparator is connected to the output of the generator 12, the information input with the first bus is the third communication line, in output - with the second bus of the third communication line.

The processing device 6, containing the interface unit 14, is supplemented by a oscillating frequency generator 15 (sweep generator), which linearly changes its frequency linearly in time from f to fin, corresponding to the temperatures T (, о and in in the return and direct pipelines, respectively. on the first bus of the third communication line is carried out stepwise, and the height of each step corresponds to a change in temperature oT - the minimum resolution value of the selected quartz thermometers, for example, 0,. The number of steps N changes the frequency of the generator ora 15 when the temperature changes from T to T

makes up

T- .. T.1 M I / O

N - -tg

and taken into account by the processing device 6.

A stepwise increasing frequency on the first bus of the third communication line is generated by the device 6 periodically during polls. When the changing frequency coincides with the output frequency of the quartz thermometer 9 of the last apartment, the comparator 13 of the latter generates a pulse on the second bus of the third communication line. With the arrival of this impulse, the device 6 stops counting the steps to the increasing frequency corresponding to the fractional participation in the heat consumption of the nth apartment.

Similarly, the k-1 steps are counted; k-2 ... m ... 2.1 apartments.

from (4) m-th apartment of the entrance in accordance with the expression:

G -

where G, is the hourly average amount of heat taken into account

heat meter, in the i-th riser; GPsr hourly average number of steps corresponding to the t-th

apartment;

NCP The average hourly number of steps corresponding to the full sweep of the polling signal.

Subsequently, the system functions similarly to that described: processing devices 6 calculate the heat released from all risers of the staircase within an hour and communicate to the computing machine 8 via the second communication lines 7.

Unlike the prototype, in the inventive device, the number of the meter within the apartment to determine its share in the heat extraction is sharply reduced: in the prototype their number corresponds to the number of radiators for water heating within the apartment, and in the inventive device to the number of access risers, which reduces the cost of system as a whole. This fact is also facilitated by the fact that the cost of a quartz thermometer is not more than 30.0 thousand rubles, which is an order of magnitude cheaper than the cost of an exemplary evaporator type.

A temperature converter placed in a sleeve mounted in a pipeline cannot be shielded from the effects of heat, as in the case of the prototype, and distort the measurement information. In addition, the temperature converters in the proposed system operate in a single network, therefore, abnormal shutdowns of the readings of each temperature converter from accidental or unauthorized interference will be recorded by the system.

Authors:

Claims (4)

1. The apartment heat metering system for a single-pipe heating system, including group heat meters for measuring the amount of heat consumed by a group of apartments from each access riser of heating water with means for measuring the spilled volume V _{i of} water and the temperature difference ΔT _i in the supply and return branches of the riser and calculators for calculating the amount of heat G _i with interface units for transmitting measurement information over communication lines, information processing devices installed on a group of heat meters for summation

the amount of heat consumed by a group of apartments from all risers of the staircase, the interface inputs of which through the first communication lines are connected to heat meters, and their interface outputs through the second communication lines are connected to an electronic computer, characterized in that for calculating the share of each apartment in the heat extraction from of each access riser, it is supplemented by temperature converters installed in each apartment for each access riser when they enter the apartment in the area of the floor, you the passages through the third communication lines are connected to information processing devices in which the share in the heat consumption of the k-th apartment from the i-th access riser is calculated in accordance with the formula

where ΔT _ki is the floor difference in temperature for the k-th apartment in the i-th riser,
and the total amount of heat consumed by the k-th apartment from all risers of the staircase brought to it is determined by the expression

where m is the number of access risers brought to the k-th apartment. 2. The accounting system according to claim 1, characterized in that the heat calculation algorithm consumed by the k-th apartment from the i-th riser, implemented by the group heat meter, is described by the expression
G _ki = V _i • ΔT _ki
3. The accounting system according to claim 1, characterized in that the temperature converters installed in the apartments have a network interface.  4. The accounting system according to claim 1, characterized in that quartz thermometers are used as temperature converters, supplemented by frequency comparators, the reference inputs of which are connected to the output of the quartz thermometer, the information input is connected to the first bus of the third communication line, and the output to the second bus the third communication line, and the processing device is supplemented by a oscillating frequency generator linearly and stepwise changing in time, the output of which is connected to the first bus of the third communication line, and the initial frequency of the generator is corresponds to the frequency of the quartz thermometer of the group heat meter in the return pipe, and the final frequency corresponds to the output frequency of the quartz thermometer in the return pipe. 5. The accounting system according to claim 3, characterized in that the processing device, when interrogating individual means of measuring temperature in apartments, generates a sweep of a linearly and stepwise changing frequency, counts the number of steps N of a sweep, receives impulse responses from individual means of measuring temperature, remembers the number of steps of change frequency corresponding to each apartment along the riser in the opposite direction and calculates the heat released m-th apartment in accordance with the expression

where G _i is the hourly average amount of heat taken into account by the group heat meter in the i-th riser;
m _{with p} is the hourly average number of steps obtained by polling the mth apartment;
N _{with p} is the hourly average number of steps corresponding to the full scan of the interrogating signal.