RU2576733C2 - Method of on-line detection of damaged network pipeline in multiline heating networks - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: in headers of direct and reverse system water, as well as in all direct and reverse pipelines of heating system under real-time mode the water pressure is monitored using the pressure transmitters, pressure changes with time are analyzed using the controller and PC, analysis results are supplied to Work Station of the heat source operator. At that minimum distance from system water headers to the pressure monitoring points in the pipelines going from the heat source are selected based on the inequality: 2*L_min/c_pw 〉〉 (τ_response+τ_switch.+ τ_contr.+ τ ^PC _), where: C_pw is speed of pressure waves spreading; τ_response is response time of pressure transmitters; τ_switch. is action time of switching devices; τ_contr. is time of data processing by controller; τ^PC is time of data processing and issuing to PC.

EFFECT: reduced heat energy and heating medium losses.

1 dwg

Description

The invention relates to the field of power engineering, in particular, to methods for promptly detecting a damaged network pipeline when transporting thermal energy from a heat source (CHP, boiler) to consumers in the event that energy is transferred in several directions.

In the presence of two or more directions of transmission of thermal energy, problems arise that are associated with both the operation of the heat source itself and the heating networks. Such problems are associated with possible emergency situations, i.e. deviations from normal operating conditions. This can be caused, for example, by the following reasons: rupture of heating networks, unauthorized interference in the operation of heating networks, water hammer and the like.

In the event of an emergency, such as a breakdown of the network pipeline, the operating personnel of the heat source react to the situation according to the testimony of a standard flow meter (heat meter) installed on the make-up pipeline, as well as pressure changes in the forward and reverse network pipelines. And if one heat main departs from the heat source, then the actions are greatly simplified by the presence of only one direction of heat output.

In the presence of two or more thermal outlets (highways) from the heat source, this problem is significantly complicated due to the high speed of the hydrodynamic processes taking place, since pressure waves (disturbances) propagate through the pipelines at a speed close to the speed of sound in a given medium. And the personnel of both the heat source and the district of heating networks (RTS) traditionally operates in accordance with standardly approved instructions for the elimination of emergency situations in the heat source and in heating networks.

The problem is that after receiving signals from the above devices about an emergency situation in just a few seconds it will be practically impossible to reliably determine the direction from which the disturbance came. And in the presence of several directions of supply of thermal energy, the actions of personnel are largely intuitive. And this, in turn, can lead to the development of an emergency not only in heating networks, but also in the heat source, up to its complete stop in conditions of low outdoor temperatures.

A known method of monitoring the pipeline and trapping leaks [1], including connecting each section of the pipeline with a storage tank, the filling time of which is judged on the nature of the leaks. In all controlled sections of the pipeline, leak traps are installed at the pipe joints, interconnected by a small flexible pipeline laid along the controlled pipeline with a slope towards the storage tank to collect leaks, which is located on the site with a minimum terrain mark.

This method is designed mainly for scheduled maintenance of pipelines. Its disadvantage is the inability to quickly respond to force majeure circumstances, such as, for example, rupture of the pipeline.

There is also a method of detecting leaks in an underground pressure pipe [2]. The method is implemented by sequentially moving the acoustic sensor along the pipeline route, recording and comparing the signals. In order to increase the reliability of detecting leaks in conditions of intense urban noise interference, registration is carried out simultaneously using several sensors that are installed along the route with an interval exceeding the depth of the pipeline and move them along the route with a step equal to the interval between the sensors, and the signal is recorded for a time exceeding the duration of the pulse interference.

As previously discussed method, this method also does not provide the ability to quickly respond to emergency situations that arose during the operation of heating networks.

Also known is a method of determining the moment and place of a leak in a pipeline [3]. When determining the moment and place of a leak in the inner pipe of the coaxial pipeline connecting the heat source to the consumer, the temperature of the heat carrier at the outlet of the consumer and at the entrance to the heat source is measured simultaneously, the temperature of the heat carrier at the outlet of the heat source and at the entrance to the heat consumer and the external temperature pipes at several points along the length of the coaxial pipeline. The moment of damage is determined by the simultaneous decrease in the flow rate of the coolant at the inlet to the heat source and the decrease in temperature at the inlet of the heat consumer and the increase in the temperature of the coolant at the outlet of the heat source, and the leak point is determined by the smallest change in the temperature of the outer wall of the outer pipe.

The disadvantage of the above scheme is its complexity and the high cost of the costs of technical and metrological maintenance.

Closest to the technical nature of the claimed solution is a method for determining the location of a leak in closed heating networks [4]. The objective of the method is to increase the accuracy of determining the location of the leak, which reduces the time for subsequent search for the point of leak. The pressure in the return manifold is measured at two feed water rates and the same coolant flow rate. The pressure at the point of leakage P is calculated from the obtained pressures and recharge costs. On the piezometric graph of the network, points with pressure P and their corresponding places on all sections of the network are marked. A specific leaky section is determined by reducing the leakage rate during sequential throttling of the coolant flow rate in each section.

The disadvantage of this method is the lack of responsiveness for the maintenance personnel of the heat source and the district heating networks. It can only be used to search for leaks, the fact of which has already been established.

All the considered methods in the presence of two or more directions of heat output do not work efficiently, since the operating personnel of the heat source and RTS are forced to search for an emergency network pipeline by switching off the main pipelines one by one. This process is stretched in time and leads to all the above problems.

The objective of the present invention is the localization of an emergency in a branched multi-line heating network by quickly detecting the direction of the resulting disturbance in the specified branched network.

The problem is solved by the fact that in the collectors of direct and reverse network water, as well as in all direct and return pipelines of a branched multi-line heating network, the water pressure is monitored in real time using pressure sensors, and the pressure changes in time are analyzed using a controller and a PC. The results of the analysis are issued at the automated workstation of the operator of a thermal power station or a boiler room. In this case, the minimum distance from the network water collectors to the pressure monitoring points in the network pipelines is chosen based on the inequality:

Where:

C _vd is the velocity of propagation of pressure waves;

τ _off. - response time of pressure sensors;

τ _commut. - response time of switching devices;

τ _counter - information processing time by the controller;

τ ^pc - processing time and outputting information to the operator on the PC.

The proposed method is illustrated by a figure, which depicts a heating network having two heating mains for transmitting thermal energy in two directions. Moreover, in the figure, all the components of the heating network are shown in bold lines, and the electrical connections between the components necessary for the implementation of the proposed method are shown in thin lines.

The heating network operates as follows. In a CHPP or boiler room 1, water (not shown in the figure) heated in hot water boilers or boilers is supplied through pipe 2 to a collector 3 of direct network water. Next, the water enters the direct network water pipe 4 of the heating main A through the shutoff valves 6 and the flow meter 7, and into the direct network water pipe 5 of the heating main B through the shutoff valves 8 and the flow meter 9. Having reached consumers through pipelines 4 and 5, the water gives up part of its heat energy. Further, through the pipeline 10 return network water (for heating main A) and then through the flow meter 12 and shutoff valves 13, as well as through the pipe 11 reverse network water (for heating main B) and then through the flowmeter 14 and shutoff valves 15, the cooled water enters the collector 16 reverse network water. From the collector 16 through the pipe 17, water enters the boilers or boilers, while part of the water lost during transportation through the heating network through the pipe 18 through the valve 19, the flow meter 20 and the collector 16 also enters the heat source for constant heating. And then everything repeats.

With this configuration of the heating network in the event of an emergency, for example, on a direct network pipeline of the heating main A (the figure shows a breakthrough of the pipeline with the symbol 21), the operational personnel of the heat source will initially record the situation regarding the operation of the process alarm and the established standard pressure gauges (not shown in the figure) , which record the pressure drop network water. In addition, the flow meter 20 will show a spasmodic increase in the flow rate of makeup water, and the valve 19 will open completely. The increase in the difference between the flow rates of the network water in the direct and return pipelines of the heating main A will not be monitored by the staff due to the incommensurability of the magnitude of the increased growth of the feed and the difference in the nominal costs in the direct and return network pipelines. That is, personnel initially will not be able to unambiguously determine the direction of the disturbance that has arisen.

To implement the proposed method in the heating system install additional components and equipment. In collectors of direct 3 and return 16 of network water, as well as in all direct and return pipelines of the heating network 4, 5, 10, and 11, pressure sensors 23, 24, 25, 26, 27, and 28 are installed with a technically minimum possible response time. And directly on the territory of the thermal power station (boiler room), a controller 29, a PC 30 are installed and an operator’s automated workstation (AWP) 31 is created. The electrical connection between additionally installed components and equipment is shown in the figure by thin lines.

Now, in the event of an emergency, for example, on a direct network pipeline of the heating main A, as a result of monitoring the pressure in real time, processing the information by the controller and the PC and supplying it to the workstation, the TPP (boiler room) operator will record the fact that the pressure wave passed through the sensors in the following order : sensor 25 → sensor 23 → sensor 26. This will unambiguously determine the occurrence of a disturbance precisely on the direct network pipeline of the heating main A or on the adjacent intra-quarter network connected to nnomu main pipeline.

A similar situation will occur in the event of an emergency, for example, on the return network pipeline of the heating main B (the figure shows the rupture of the pipeline at 22). Then the pressure sensors will show the propagation of the pressure wave in the following order: sensor 28 → sensor 24 → sensor 27. This will clearly indicate the direction of the disturbance in order to make the right decision for the operating personnel.

A prerequisite for the correct operation of the proposed method is the sufficient distance (L _min ) of the points where the pressure is recorded in real time by the sensors 25, 26, 27 and 28 of the sensors 23 and 24. Otherwise, it may turn out that the transit time of the pressure wave in case of an emergency less than the response time of the whole complex of equipment, which will not allow to reliably determine the direction of emergencies. Therefore, when choosing the points of placement of pressure sensors, the following inequality must be fulfilled:

Where:

C _vd is the velocity of propagation of pressure waves;

τ _off. - response time of pressure sensors;

τ _commut. - response time of switching devices;

τ _counter - information processing time by the controller;

τ ^pc - processing time and outputting information to the operator on the PC.

Thus, the implementation of the method will solve the following technical and economic problems:

1. Quickly and unambiguously determine the specific network pipeline where an emergency occurred, correctly direct the emergency brigade of heating networks and prevent the development of an emergency on the heat source.

2. To reduce the costs associated with the loss of thermal energy and coolant in emergency situations, transport and labor costs for finding emergency sections of the heating network.

Accepted Conventions

1 - CHP (boiler room);

2 - pipe supply to the collector direct network water;

3 - collector direct network water;

4 - pipeline direct network water heating line A;

5 - pipeline direct network water heating main;

6 - shutoff valves;

7 - flow meter;

8 - shutoff valves;

9 - flow meter;

10 - return pipe network water heating line A;

11 - pipeline return network water heating main;

12 - flow meter;

13 - shutoff valves;

14 - flow meter;

15 - shutoff valves;

16 - collector reverse network water;

17 - pipe drain from the collector reverse network water;

18 - pipe for supplying water to feed the heating network;

19 - valve;

20 - make-up water flow meter;

21 is a schematic illustration of a pipe break in a heating main A;

22 is a schematic illustration of a pipe break in a heating main B;

23 - pressure sensor in the collector direct network water;

24 - pressure sensor in the collector of reverse network water;

25 - pressure sensor in the pipeline direct network water of the heating main A;

26 - pressure sensor in the pipeline direct network water of the heating main;

27 - pressure sensor in the pipeline return network water of the heating circuit A;

28 - pressure sensor in the pipeline return network water of the heating main;

29 - controller;

30 - PC;

31 - automated workplace of the operator (AWP)

Information sources

1. RU 2106570 C1, cl. F17D 5/02, 03/10/1998.

2. SU 1216550 A1, cl. F17D 5/02, 03/07/1986.

3. SU 1260633 A1, cl. F17D 5/02, 09/30/1986.

4. SU 1652848 A1, cl. G01M 3/28, 05/30/1991.

Claims (1)

A method for promptly detecting a damaged network pipeline of a multi-line heating network extending from a heat source, characterized in that in the collectors of direct and reverse network water, as well as in all direct and reverse pipelines of the heating network, the water pressure is monitored in real time using pressure sensors, and the change is analyzed pressure in time with the help of the controller and personal electronic computer and the results of the analysis are given to the operator’s workstation source, while the minimum distance from the network water collectors to pressure monitoring points in the pipelines leaving the heat source is chosen based on the inequality:

Where:
C _vd is the propagation velocity of pressure waves;
τ _off. - response time of pressure sensors;
τ _commut. - signal transmission time over communication lines,
τ ^PC - the processing time of the corresponding program and the issuance of information by a personal electronic computer to the operator.