RU2273833C1 - Method of measuring discharge of thermal energy of user with vertical and other types of arrangement of thermal sources - Google Patents

Abstract

FIELD: heat engineering measurement technology.

SUBSTANCE: temperature difference range of heat source operation is established. Heat discharge factor corresponding to any temperature range is determined empirically. Temperature difference between surface of heat source and environment is determined in turn for all the sources as often as any 0,2-1 hour. Thermal energy consumed by any of any heat source and total consumption are measured.

EFFECT: simplified procedure of measurement; improved precision of measurement.

1 dwg

Description

The invention relates to heat engineering measurements and allows to determine the consumption of thermal energy of the consumer with vertical and other types of wiring of heat sources according to only one variable parameter - the temperature difference. It can be used in the urban economy to determine the consumption of thermal energy in the premises (apartment, office, cottage, etc.), as well as to measure and control the consumption of thermal energy in various technological processes.

Currently, they mainly use a method for determining the consumption of thermal energy by the amount of coolant passed and the difference in its temperatures at the inlet and outlet, i.e. according to two variable parameters (heat meters). However, this method is intended only for horizontal wiring of the heating system and its use for the vertical wiring of the heating system adopted in the Russian Federation is unprofitable (see AS USSR No. 932292, G 01 K 17/06, 82)

In thermotechnical measurements, the second method is also known for determining the consumption of thermal energy according to the Newton-Richmann formula, i.e. by the temperature difference between the surface of the heat source and the environment and by the heat transfer coefficient, i.e. by two variable parameters. Many experts and inventors have tried to simplify the calculation of the flow rate using the above formula, especially the definition of a complex heat transfer coefficient, which is calculated using the Groshoff, Prandtl, Nusselt criteria, average temperature, temperature difference, air parameters - thermal conductivity coefficient, viscosity coefficient, volume expansion coefficient during each measurement etc., which change their parameters when the temperature changes, but so far this problem has not been solved. Therefore, this method is practically not used to determine the consumption of thermal energy.

As an example of attempts to simplify the calculation of the heat transfer coefficient, one can consider a.s. USSR No. 1781563, G 01 K 17/20, 92, "Method for determining the local heat transfer coefficient", which consists in installing a heat flux sensor to the heat source, which is heated by a pulse current and at the moment the temperature of the sensor and the heat source is equal to the heat flux, ambient temperature and the temperature of the sensor determine the value of the local heat transfer coefficient.

There is a patent RU No. 2095769, G 01 K 17/20, 97 g. "A device for accounting the heat energy consumption of a heating device, in which the heat transfer coefficient calculation unit determines it by a linear dependence on the temperature difference with an accuracy of only ± 5%.

However, all attempts led to the complication of determining the heat transfer coefficient or lowering the accuracy of its determination.

The closest in technical essence is the "Method for determining heat consumption by local consumers included in the integrated system of heat consumers." Patent RU No. 2138029, G 01 K 17/08, 1998

The essence of this invention lies in the fact that the authors understand the local consumer as an apartment, and the whole house as a united consumer system. First, the authors in a known manner, using a heat meter for horizontal wiring, determine the heat energy consumption of the entire house, and then it is distributed to each apartment, but not as is currently accepted by the area of the apartments, but according to the Newton-Richman formula. For this, temperature sensors are installed on each battery in each apartment in the house, connected in series to determine the average temperature difference in the apartment and throughout the house. Then determine the total surface area of the batteries for each apartment and throughout the house. The average heat transfer coefficient of the whole house is determined by the Newton-Richman formula from the consumption of thermal energy for the whole house, the surface area of the batteries of the whole house and the average temperature difference of the whole house. Then, the values of the average heat transfer coefficient, the average temperature difference of the apartment, the surface area of the battery of the apartment are introduced into the same formula and the consumption of the apartment is determined, i.e. In fact, this is not a way to determine the flow rate by a local consumer, but one way of distributing a known flow rate to the entire house for each local consumer. For this distribution, in addition to installing a large number of temperature sensors and communication cables, a KVP unit is installed in each apartment, which determines the temperature difference and transfers it to the PC unit. At the same time, data on the average heat transfer coefficient are received from the DC home concentrator in the PC unit and the PC determines the heat consumption of a specific consumer (apartment).

The disadvantages of this method are:

- low accuracy of the distribution of consumption for each apartment, comparable with the distribution over the area of apartments, which is associated with improper use of the Newton-Richman formula, which suggests that the parameters included in it are used from only one heat source, and then the resulting costs from each heat source can be added, but not vice versa, as the author of the patent suggested,

- the complexity and high cost of this method,

- a large number and large length of communication lines,

- the impossibility of applying this method if one or more apartments of an apartment building refuse to install an apartment device for determining the temperature difference and temperature sensors on batteries and in rooms.

From the foregoing, we can conclude that at present there is no way to determine the consumption of thermal energy for vertical wiring of heat sources, because its determination is carried out with low accuracy or in general the measurement is unprofitable. However, the government of the Russian Federation and city halls prescribe the installation of such devices, as heat metering apartment by apartment gives a big saving of heat and energy resources - up to 30-40%.

The objective of the invention is to create a simple and inexpensive method for determining the consumption of thermal energy of the consumer with vertical and other types of wiring of heat sources and improving the accuracy of measurement.

The essence of the claimed invention "A method for determining the consumption of thermal energy of a consumer with vertical and other types of wiring of heat sources" is as follows. First, once set the temperature difference range of the heat sources and the table determines the corresponding coefficient of heat consumption. After that, the temperature difference between the surface of the heat source and the environment is determined periodically with a frequency of 0.2 to 1.0 hours in turn for all heat sources, and then the heat energy consumption of each heat source and the entire consumer as a whole is determined by the formula:

Q = (K · ΔT1 · S1 · t) + ... + (K · ΔTn · Sn · t)

where: Q is the consumption of thermal energy of the consumer,

ΔTn is the temperature difference "n" of the heat source,

Sn is the surface area "n" of the heat source that gives off heat,

K is the coefficient of heat consumption,

t is the flow rate

n is the number of heat sources in the consumer,

table range ΔТ ° С coefficient of flow. heat K 0-80 1.32 50-450 0.96 420-820 0.77 790-1190 0.65

The indicated physical formula and table were obtained empirically by the applicants. At first, the formula was derived for the functional curvilinear dependence of the heat transfer coefficient on the temperature difference, which increased the measurement accuracy. Then, instead of the heat transfer coefficient, the formula of its functional dependence on the temperature difference was introduced into the Newton-Richmann formula. The analysis of the obtained physical formula showed that when changing the temperature difference range of the heat source, the formula does not change, but only the heat consumption coefficient specified in the table changes.

The frequency of measuring the temperature difference with a frequency of 0.2 to 1.0 hours is determined by the mass of the heat source and the heat carrier, as well as the time it takes to question the heat source fans and calculate the flow rate for each heat source and the entire consumer.

From the foregoing, we can emphasize the following features of the claimed invention, which distinguish it from known inventions.

1. The method of determining the consumption of thermal energy is intended for consumers with vertical and other types of wiring of heat sources.

2. The heat transfer coefficient is expressed through a curved functional dependence on the temperature difference.

3. The functional dependence formula is also defined as the heat transfer coefficient for the maximum temperature of the range, but the temperature difference value is left in general form and the resulting formula is entered into the Newton-Richmann formula instead of the heat transfer coefficient.

4. Get only one new formula for determining the flow of thermal energy for the desired range of temperature differences, ie no additional formulas are required, for example, to determine the heat transfer coefficient.

5. Only once pre-set the temperature difference range of the heat sources and select the corresponding coefficient of heat consumption from the table.

6. Determination of the temperature difference is carried out periodically with a frequency of from 0.2 to 1.0 hours in turn for all heat sources.

7. Only by one variable parameter - temperature differences determine the flow rate of each heat source and the consumer as a whole.

8. Separately, the heat transfer coefficient is not determined.

9. Increase the accuracy of the measurement due to the use of a curved functional dependence on the temperature difference.

10. The order of calculation operations has been changed since in known inventions, in each measurement, the temperature difference is first determined, the heat transfer coefficient is calculated, and then they are introduced into the Newton-Richmann formula and the flow rate is determined, and in the declared one, the heat consumption coefficient is determined previously from the required range of the heat source operation, and then in each measurement flow rate is determined only by one variable parameter - temperature difference.

11. With respect to the prototype, the claimed method is simpler, more accurate and cheaper, i.e. it will be available to the ordinary tenant. A block diagram of one of the possible devices operating by this method is shown in the drawing. It consists of microprocessor 1, the output of which is connected to display 2, a power source 3 (lithium battery) to power the microprocessor and display, as well as temperature sensors from 4 to n, which are connected via a single-wire interface to the microprocessor input.

Previously, before installing each temperature sensor on a given heat source, the surface area of this heat source is recorded in it, and the claimed formula with the required coefficient of heat consumption is written to the central microprocessor.

The device operates as follows. The microprocessor requests data, for example, from the temperature sensor of the first heat source and receives its temperature and surface area. Then the microprocessor obtains the value of the ambient temperature and determines the temperature difference between the surface temperatures of the heat source and the medium. Based on the difference in temperature and surface area, the microprocessor calculates the heat energy consumption of a given heat source using the recorded formula and the result is summed up in the microprocessor's memory and displayed. Then, the microprocessor requests the data of the next heat source and the cycle is repeated until the last heat source entering the consumer, and the sum of all the expenditures of thermal energy of the heat sources stored in the memory is the consumption of thermal energy of the consumer. Then the microprocessor goes into low power mode and waits for a signal to turn on. After a predetermined time (from 0.2 to 1.0 hours), the microprocessor enters the operating mode and the entire polling cycle, the consumption of heat energy of the heat sources and the entire consumer is repeated, etc. By pressing the power button of the display, the consumer reads the consumption of thermal energy for the required time. The difference between the last readings and the previous ones for a certain time is the consumption of thermal energy during this time.

Using the claimed method will allow;

- improve the accuracy of determining the flow of thermal energy,

- determine the consumption of thermal energy in a direct, but not indirect way through the coolant,

- determine the consumption of thermal energy of the consumer with any type of wiring heat sources (vertical, horizontal, mixed, etc.), with any type of coolant (water, steam, oil, antifreeze, etc.) and other internal heatings (electrical, chemical electrochemical, atomic, etc.),

- install only one device per consumer,

- install the elements of the device without insertion into the heating system,

- to simplify the device and significantly reduce its cost, so that it is available to the ordinary tenant.

Claims (1)

A method for determining the consumption of thermal energy of a consumer with vertical and other types of distribution of heat sources, including determining the temperature difference between the surface of the heat source and the environment, characterized in that the temperature difference between the temperatures of the heat sources is set once and the table determines the corresponding heat consumption coefficient, after which determination of the temperature difference between the surface of the heat source and the environment is carried out periodically with a frequency of 0.2 to 1.0 hours alternately for all heat sources, and then determine the flow of heat energy of each heat source and the entire consumer as a whole according to the formula Q = (K · ΔT ₁ ^4/3 · S ₁ · t) + ... + (K · ΔT n 4/3 · S n · t), where Q is the consumption of thermal energy of the consumer; ΔT _n is the temperature difference n of the heat source; S is the surface area n of the heat source that gives off heat; K is the coefficient of heat consumption; t is the flow rate; n is the number of heat sources in the consumer. Range ΔТ ° С Heat consumption coefficient K 0-80 1.32 50-450 0.96 420-820 0.77 790-1190 0.65