RU2247340C2 - Multifunctional heat meter - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: multifunctional heat meter comprises heat sensors connected with the computing device. The computing device has computing unit for calculating heat flux connected with the unit of correcting coefficients. One of the heat sensors is mounted on the surface of the heat source, and the other one is mounted at the level of the bottom boundary. The heat consumption is calculated from the formula proposed.

EFFECT: enhanced accuracy of measurements.

1 cl, 1 dwg

Description

The invention relates to heat engineering and can be used to account for heat consumed by a local consumer, which is an integral part of the integrated consumer system, for example, in utilities for metering the heat consumed by a separate apartment in an apartment building.

The well-known "Method of local control and accounting of heat consumption" according to the patent of Russia No. 2105958, class. G 01 K 17/00, 17/08, published in BI No. 6, 02/27/98.

The essence of this invention is as follows: with the help of thermal converters, the differences in the temperature of the coolant at the input and output of the thermal installations are measured, and the levels of signals supplied from the thermal converters are created proportional to the relative nominal thermal capacities of the respective thermal installations, ensuring proportionality of the total signal level to the total consumption of thermal energy. A device for implementing this method should be equipped with thermal converters and a calculation circuit.

However, the widespread use of this method is irrational for the following reasons:

- due to the high cost of thermal converters;

- almost unlimited range of types of thermal converters due to the variety of installations;

- a large number of communication lines connecting the thermocouples to a temperature difference measuring device;

- the temperature difference at the inlet and outlet of the heating radiators is insignificant and can be taken into account only with a sufficiently accurate, and therefore expensive, instrument;

- to install thermal converters and measure the temperature of the coolant, it is necessary to violate the integrity of the battery or heating pipe, which is fraught with leaks or even the creation of an emergency.

Also known is the “Method for determining heat consumption by local consumers included in the integrated system of heat consumers” according to the patent of Russia No. 2138029, class. G 01 K 17/08, published in BI No. 26, 09/20/99

The essence of this invention is as follows: determine the total heat consumption for the entire house using a heat meter that measures the temperature of the coolant, then divide this figure by the total surface area of the batteries (heat sources) installed in the house, multiplied by the temperature difference between the surface of the heat source and environment and heat transfer time, and the resulting coefficient, called by the authors the average heat transfer coefficient for the combined system, is multiplied by the surface area of heat sources installed in each apartment, and the temperature difference measured in each apartment.

To determine the heat consumption, for example, in a single apartment in a multi-storey apartment building with vertical (traditional) or horizontal wiring of heating pipes, first determine the heat consumption throughout the house using a heat meter for the entire house. A home information concentrator (DKI) is connected to the heat meter, which contains information on the heat transfer surface area for each apartment in this house. In DKI data on the temperature difference from the devices of local heat consumers are given at certain points in time, and the temperature on the heat transfer surface of the relative devices (batteries) and the temperature of the cooling medium (air at the floor level in the room) are constantly recorded.

Knowing the heat consumption by the integrated system of heat consumers for a specific time (according to the readings of the home heat meter), the DKI calculates the average heat transfer coefficient from the integrated system of heat consumers. And then, DKI calculates the heat consumption for a specific local consumer, as the product of the average heat transfer coefficient for the combined system of heat consumers by the heat transfer area of this local consumer, by the temperature difference on the surface of the heat source and the environment of the local consumer, and multiplied by the same time, which was determined by the heat consumption by the integrated system. Having calculated the amount of heat for each local consumer, the DKI transmits this information to the corresponding metering device of the local consumer with a constant accumulation of information on heat consumption.

The determination of heat consumption by a local consumer in the manner described above is not a measurement of the amount of heat consumed by a particular apartment, but is only the distribution of payment for heat received by the entire house between tenants in proportion to the surface area of the batteries installed in his apartment. If at least one of the consumers refuses to install temperature sensors in his apartment, the system is deprived of the possibility of application for other consumers in this building.

The invention solves the problem of determining heat consumption by each local consumer, independently of other consumers.

To solve the problem in a multifunctional heat meter containing temperature sensors connected to a calculation device, which contains a computing unit for calculating heat consumption, connected to a block of correction coefficients, the calculation of heat consumption occurs in accordance with the formula:

Q = Σ Q ₁ β ₁ β ₂ + Q ₂ + Q ₃ ,

where Q ₁ - part of the estimated heat loss by the building, compensated by heating devices;

β ₁ is the coefficient of accounting for the additional heat flux of the installed heating devices due to rounding in excess of the calculated value;

β ₂ is the coefficient of accounting for additional heat loss by heating devices located at the outer fences;

Q ₂ - additional heat loss during cooling of the coolant in the supply and return lines passing in unheated rooms, kW, determined by calculation;

Q ₃ - part of the calculated heat loss, compensated by heat from pipelines passing in heated rooms, kW.

The value of Q _{1 is} calculated from the Newton-Richmann formula:

Q ₁ = α _nar · S _mu (t _mu -t _air ),

where α _nar is the heat transfer coefficient from the heated surface of the heat source to the surrounding air;

S _mu is the surface area of the heat source;

t _mu is the temperature of the outer surface of the heat source;

t _air - temperature of the air flow, suitable for the lower zone of the heat source.

Moreover, the multifunctional heat meter contains one temperature sensor mounted on the surface of the heat source, and the other temperature sensor is installed at the level of the lower boundary of the heat source.

The computing unit for calculating the heat consumption is connected to the unit for determining the emergency situation and deviations from the requirements of the standards, which in turn is connected to the emergency detector.

The drawing shows a functional diagram of the inventive multifunctional heat meter.

For each heat source 1 there are two temperature sensors. The temperature sensor 2 is located on the surface of the heat source 1. The temperature sensor 3 is located at the lower boundary of the heat source to measure the air flow suitable to the heat source. Thermal sensors 2 and 3 are connected to the computing unit 4, to the other input of which is connected the block 5 of the correction factors. The computing unit 4 is also connected to the unit 6 for determining emergency situations and deviations from the requirements of the norms. Block 4 is also connected to the indicator 7 of the indications of heat consumption. Block 6 is connected to the detector 8 emergency. The heat sources that are serviced by the inventive heat meter, there may be a sufficiently large number, for example, l. Indicators 7 and detectors 8 may also be some in terms of the number of heat consumers, for example, m.

The heat source 1 may be, for example, a central heating battery. For each battery there is a pair of temperature sensors 2 and 3, which measure the temperature difference between the surface of the heat source and the heat flux suitable for it. The computing unit 4 performs the function of calculating the heat consumption of each battery, multiplying the temperature difference by the surface area of the heat source 1, by the time and by the signal from the unit 5. Block 5 contains coefficients that take into account the material from which the heat source 1 is made, the location of the heat source 1 and other specific operating conditions of the heat source 1. The indicated coefficients are given in the special literature (see the list of references) and the possibility of their application is proved by the authors below. Computing unit 4, in addition, summarizes the heat consumption from a group of heat sources located at a separate heat consumer, for example, in a single apartment. Indicators 7 and detectors 8 are installed one per consumer, for example, one apartment.

The inventive multifunctional heat meter operates as follows. Computing unit 4 periodically sends a request signal to all temperature sensors connected to it. The signals from heat sensors 2 and 3 and other temperature sensors are fed to computing unit 4, which determines the heat consumption in each heat source 1. Information about the amount of heat is displayed by indicator 7. In addition, this information can be transmitted to the base station to the controlling organization. Computing unit 4 controls the compliance of the parameters of the air temperature in the room and the parameters of the heat source with the requirements of the norms and takes into account how long these requirements were violated. Computing unit 4 based on the readings of temperature sensors can detect an emergency and give a signal to block 6 and detector 8. The detector can be a siren, a light signal, in addition, an alarm signal can be sent directly to emergency services. Structurally, the functions of blocks 4, 5, 6 are performed by a microprocessor.

The calculation of heat consumption is in accordance with the formula, which is given in [1]

Q = Σ Q ₁ β ₁ β ₂ + Q ₂ + Q ₃ ,

where Q ₁ - part of the estimated heat loss by the building, compensated by heating devices;

β ₁ is the coefficient of accounting for the additional heat flux of the installed heating devices due to rounding in excess of the calculated value;

β ₂ is the coefficient of accounting for additional heat loss by heating devices located at the outer fences;

Q ₂ - additional heat loss during cooling of the coolant in the supply and return lines passing in unheated rooms, kW, determined by calculation;

Q ₃ - part of the calculated heat loss, compensated by heat from pipelines passing in heated rooms, kW.

The value of Q _{1 is} calculated from the Newton-Richmann formula:

Q ₁ = α _nar · S _mu (t _mu -t _air ),

where α _nar is the heat transfer coefficient from the heated surface of the heat source to the surrounding air;

S _mu is the surface area of the heat source;

t _mu is the temperature of the outer surface of the heat source;

t _air - temperature of the air flow passing to the lower zone of the heat source.

From [2, 3] the expression is known:

Nu = c · (Gr · Pr) ^h ,

where Nu is the Nusselt number,

Gr is the Graeghoff number,

Pr is the Prandtl number,

c is a constant for free convection;

h is the height of the wall of the heat source.

Nusselt number is expressed as

where λ _air - the coefficient of thermal conductivity of air.

Graegoff number can be expressed:

where g is the acceleration of gravity,

- коэффициент объемного расширения воздуха,

- coefficient of volume expansion of air,

T _abs is the absolute temperature of the air,

Δ T = t _mu -t _air - see above,

υ is the coefficient of kinematic viscosity of air.

Prandtl number can be expressed

where a is the coefficient of thermal conductivity of air.

The above values of g, β _air , υ, a, Pr are tabular data published in [2].

The expression is known (see [2]).

where c is a constant for free convection,

n is an indicator of the degree of influence,

The values of g, β _air , υ, and, Pr used above are tabular data [4].

In turn, the relation is known [2]

where n is an indicator of the degree of influence,

where can I find

For free convection at a vertical heated surface at

(Gr · Pr)> 2 · 10 ⁷ ,

c = 0.135;

those. can write

or α _nar = k · (t _mu -t _air ) ^1/3 ,

where k is a coefficient consisting of thermophysical constants and expressed as

In view of the above

Q = α _nar S _mu (t _mu -t _air )

we get

Q ₁ = kS _mu (t _mu -t _air ) ^4/3 .

Since k is the coefficient defined above through constants, S _{mu is} known, then Q _{1 is} uniquely determined through the difference (t _mu -t _air ).

The proposed method allows to take into account the heat consumption of each consumer, taking into account its specific conditions.

The inventive multifunctional heat meter is an inexpensive device available for every consumer, can be installed in any building, including an apartment building, regardless of the desire of other consumers. The inventive heat meter allows you to timely determine the presence of an emergency and report it to the consumer and emergency services.

Literature

1. SNiP 2.04.05-91. Appendix 12.

2. Mikheev M.A., Mikheeva I.M. The basics of heat transfer. M., 1982 - 320 p.

3. Heat engineering reference book. T.1. M., 1976.

4. Heating and ventilation. Part 1. M., 1975.

Claims (2)

1. A multifunctional heat meter containing temperature sensors connected to a calculation device, the calculation device comprising a computing unit for calculating heat consumption connected to a block of correction coefficients, one of the temperature sensors is installed on the surface of the heat source, and the other temperature sensor is installed at the lower boundary, when this heat consumption is reflected in the indicator, characterized in that the calculation of heat consumption occurs in accordance with the formula Q = Σ Q ₁ β ₁ β ₂ + Q ₂ + Q ₃ , where Q ₁ - part of the estimated heat loss by the building, compensated by heating devices; β ₁ - coefficient of accounting for the additional heat flux of the installed heating devices; β ₂ is the coefficient of accounting for additional heat loss by heating devices located at the outer fences; Q ₂ - additional heat loss during cooling of the coolant in the supply and return lines passing in unheated rooms; Q ₃ - part of the estimated heat losses compensated by the heat input from pipelines passing in heated rooms; the value of Q _{1 is} calculated by the formula Q ₁ = kS _mu (t _mu -t _air ) ^4/3 , where k is the coefficient consisting of thermophysical constants; S _mu is the surface area of the heat source; t _mu is the temperature of the outer surface of the heat source; t _air - temperature of the air flow, suitable for the lower zone of the heat source. 2. The multifunctional heat meter according to claim 1, characterized in that the computing unit for calculating the heat consumption is connected to the emergency determination unit and deviating from the requirements of the norms, which is connected to the emergency detector.