RU2484381C1 - Continuous monitoring method and system of availability and localisation of section of interpenetration of network heat carrier and heated water in heat exchange equipment of centralised heat supply system - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: continuous monitoring method of availability and localisation of interpenetration section of a network heat carrier and heated water in heat exchange equipment of the centralised heat supply system involves measurement of dielectric permeability, specific electric conductivity, temperature and pressure of heat carrier and heated water; correction of the measured values to the set fixed temperature and pressure values, analysis of dynamics of change of the measured values, determination of availability and degree of interpenetration of heat carrier and heated water in a certain heat supply section. Besides, the proposed invention describes the continuous monitoring system of localisation of interpenetration section of the network heat carrier and heated water in heat exchange equipment of the centralised heat supply system for implementation of the continuous monitoring method of availability and localisation of interpenetration section of network heat carrier and heated water in heat exchange equipment of the centralised heat supply system.

EFFECT: reliable and uninterrupted monitoring of leaks in power equipment of heat supply systems.

2 cl, 2 dwg

Description

The present invention relates to the field of heat and water supply of housing and communal services, as well as industrial, transport and agricultural enterprises.

Prepared water with normalized parameters for oxygen content is used as a heat carrier in heat supply systems to minimize the corrosion process and in terms of stiffness in order to protect pipeline structures and heat exchange equipment from deposition of poorly soluble magnesium and calcium salts on their internal surfaces. The penetration of water into the coolant from the water supply system through the leaky places of the heat exchange equipment that arose during operation is one of the main reasons for the decrease in the efficiency and failures of heat supply systems. Accordingly, the timely identification and localization of places of interpenetration of the coolant and water will be one of the factors affecting the increase in energy conservation.

As the closest analogue of the present invention, a method for measuring the flow rate and degree of contamination of the liquid, based on measuring the dielectric constant of the medium flowing in the pipeline, and described in patent RU 2130170, published on 05/10/1999. According to the method known from RU 2130170, on the basis of the measured value of the dielectric constant and the resonator frequencies, a conclusion is made about the flow rate of the liquid in the pipeline and the degree of its contamination. Obviously the use of this method in various systems for monitoring the qualitative and quantitative characteristics of the liquid in the pipelines. In this case, the main disadvantage of the method known from RU 2130170 and, accordingly, control systems based on its use, is the exclusion from the measurements and, accordingly, from the analysis of the temperature and pressure of the medium. This drawback, on the one hand, will lead to significant errors in determining the necessary parameters, and on the other hand, it will not allow an adequate analysis of the dynamics of parameter measurements at various points and, therefore, to use this method to determine the presence and location of mutual penetration of the network coolant and hot water through leaks in hot water heat exchangers and mixing equipment.

In turn, the present invention will eliminate this drawback and propose a method for continuously monitoring the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment: the flow of hot water into the network coolant or leakage of the network coolant into the hot water supply system of consumers. According to the method, a system is proposed for continuous monitoring of the presence and localization of the site of interpenetration of the network coolant and heated water in heat exchange equipment.

A method for continuously monitoring the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment of the district heating system includes: measuring the dielectric constant and electrical conductivity, as well as the temperature and pressure of the coolant in the supply and return network pipelines of the heat point; measurement of dielectric constant and electrical conductivity, as well as temperature and pressure of the heat carrier and the heated aqueous medium at the inputs and outputs of the heat exchange equipment of the heat point along the direction of the heat carrier and the heated medium, respectively; measurement of dielectric constant and electrical conductivity, as well as temperature and pressure of the heated aqueous medium at points of additional control inside the heat exchange equipment of the heat point. The measured values of the dielectric constant and electrical conductivity of the coolant and the heated aqueous medium are reduced to a fixed value of temperature and pressure. An analysis is made of the dynamics of changes in the measured values of the dielectric constant and electrical conductivity at the aforementioned fixed value of temperature and pressure. As a result, the presence and degree of interpenetration of the coolant and the heated aqueous medium in a particular section of the heat supply system are determined based on the identified dynamics of the change in the measured values of the dielectric constant and electrical conductivity.

The system of continuous monitoring of the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment of the district heating system includes a set of capacitive type transducers for measuring electrical capacitance (permittivity) and electrical resistance (electrical conductivity), as well as a set of primary transducers for measuring pressure and temperature. These primary converters are located on the supply and return network pipelines of the heat point, at the inputs and outputs of the heat exchange equipment of the heat point along the direction of the heat carrier and the heated medium, as well as at points of additional control inside the heat exchange equipment of the heat point along the course of the heated medium. The system also includes a set of secondary transducers connected to the primary transducers, supplying the primary transducers with current signals of predetermined parameters and receiving reaction signals of the medium for subsequent processing; and an automated workstation for monitoring primary converters, visualizing the operations of monitoring, collecting, processing and storing information connected to a block of secondary converters through a wired channel.

The proposed method and device are illustrated by drawings.

Figure 1 - block diagram of the proposed method.

Figure 2 is a structural diagram of a district heating system, equipped with the means of the proposed system.

The proposed system for continuous monitoring of the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment of the district heating system includes a set of primary converters of capacitive type 1 for measuring electric capacitance (dielectric constant) and electrical resistance (specific conductivity), as well as a set of primary converters 1 for pressure and temperature measurements, a set of secondary transducers 2 connected to the primary converters, and an automated workstation 3 for monitoring primary converters, visualizing the operations of monitoring, collecting, processing and storing information, connected to the secondary converters block via a wired channel. The primary converters 1 are placed on the supply and return network pipelines of the heat point, at the inputs and outputs of the heat exchange equipment 4 of the heat point along the direction of the heat carrier and the heated medium, as well as at points of additional control inside the heat exchange equipment 4 of the heat point along the course of the movement of the heated medium. The number of primary converters 1 is determined depending on the complexity of the design and the need for accurate localization of the leakage site. Secondary converters can be combined into a separate structural unit or carried out distributed according to the principle of an intelligent sensor. Secondary transducers 2 provide current signals of predetermined parameters to the primary converters 1 — the voltage exposure of a given frequency and amplitude and the receipt of medium response signals for subsequent processing on the basis that the magnitude and phase shift of the response signal depend on the electrophysical characteristics of the controlled fluid.

From the secondary converters 2, the arrays of recorded current and voltage values for the respective control channels are continuously transmitted to the automated workstation 3 of the control of the primary converters. Automated workstation 3 for each channel calculates the values of electrical resistance and electric capacity from the data arrays, the latter are converted into specific indicators: electrical conductivity and permittivity, respectively, after which they are brought to uniform conditions for the measured temperature and pressure. Automated workstation 3 compares the given values of the electrophysical characteristics of the coolant and hot water in the order of their direction of movement and calculates the degree of penetration of the heated aqueous medium into the coolant as the concentration of one medium in another. In the opposite case, the automated workstation 3 at each of the sections between the primary converters predicts leakages, and also performs the functions of warning and alarm, including the formation of commands to turn off the emergency zones of the heat circuit, the functions of visualizing continuous monitoring operations, and the communication functions with the automated centralized control system heat supply area, archiving of measurement and control results. In addition, additional functions for monitoring the quality of the coolant and the heated medium by complex electrophysical parameters can be superimposed on the workstation 3.

Using the proposed method and system, utilities can quickly respond to violations of the integrity of the structures of water supply and heat supply systems. In particular, if hot water supply of increased rigidity and oxygen content enters the coolant when promptly eliminating leaks, the likelihood of formation of insoluble and characterized by low thermal conductivity salt deposits on the surfaces of the heat exchange equipment will be significantly reduced, and the intensification of the corrosion process will be excluded. An operative reaction to the ingress of coolant into tap water will make it possible to exclude the ingress of substances hazardous to human health. Obviously, at the same time as analyzing the quality characteristics, a conclusion can be made about the quality of pipelines and / or heat exchange equipment. Thus, a method and system for continuous monitoring of the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment of industrial and communal heat and hot water supply systems, which will provide reliable and uninterrupted control of leaks in the power equipment of heat supply systems, is proposed.

Claims (2)

1. The method of continuous monitoring of the presence and localization of the site of interpenetration of the network fluid and heated water in the heat exchange equipment of the district heating system, including:
measurement of dielectric constant and electrical conductivity, as well as temperature and pressure of the coolant at the supply and return network pipelines of the heat point;
measurement of dielectric constant and electrical conductivity, as well as temperature and pressure of the heat carrier and the heated aqueous medium at the inputs and outputs of the heat exchange equipment of the heat point along the heat carrier and the heated medium, respectively;
measurement of dielectric constant and electrical conductivity, as well as temperature and pressure of the heated aqueous medium at points of additional control inside the heat exchange equipment of the heat point;
bringing the measured values of dielectric constant and electrical conductivity of the coolant and the heated aqueous medium to a fixed value of temperature and pressure;
analysis of the dynamics of changes in the measured values of the dielectric constant and electrical conductivity at the aforementioned fixed value of temperature and pressure;
determination of the presence and degree of interpenetration of the coolant and the heated aqueous medium in a specific section of the heat supply system, based on the identified dynamics of changes in the measured values of the dielectric constant and electrical conductivity. 2. A system for continuous monitoring of the presence and localization of the site of interpenetration of the network coolant and heated water in the heat exchange equipment of the district heating system, including:
a set of primary transducers of capacitive type for measuring electrical capacitance (permittivity) and electrical resistance (electrical conductivity), as well as a set of primary transducers for measuring pressure and temperature,
located on the supply and return network pipelines of the heat point, at the inputs and outputs of the heat exchange equipment of the heat point in the direction of the heat carrier and the heated medium, as well as at points of additional control inside the heat exchange equipment of the heat point in the direction of the movement of the heated aqueous medium;
a set of secondary converters connected to the primary converters, supplying current signals of predetermined parameters to the primary converters and receiving response signals of the reaction of the medium for subsequent processing;
an automated workstation for monitoring primary converters, visualizing the operations of monitoring, collecting, processing and storing information connected to a block of secondary converters through a wired channel.

Images