RU2774558C1 - System for remote automatic control and operation of pipelines of heating mains - Google Patents

Abstract

FIELD: pipelines.

SUBSTANCE: invention relates to the field of operation and monitoring the integrity of pipelines, in particular heating mains. The system for remote automatic control and operation of pipelines of heating mains using a wireless communication channel includes a ground carpet 1, on which at least one interface converter 2 is installed, which is a module with a programmable board with inputs for connecting signal conductors and a connector for a battery, and also equipped with a connector for connecting an external antenna, which provides communication with at least one LoRaWAN 3 wireless base station and with a wired Ethernet 4 interface for communication with a cloud data processing server 5 and a cloud data storage server 6, in addition, it has a memory for storing measured resistance data and remote transmission in automatic mode.

EFFECT: invention makes it possible to provide the possibility of remote automatic monitoring of the integrity of heating pipelines using a wireless communication channel, as well as the detection of leaks, which simplifies operation, expands functionality, and allows the introduction of a RRCS into an existing system.

1 cl, 1 dwg

Description

The invention relates to the field of operation and monitoring the integrity of pipelines, in particular heating mains, and is aimed at detecting leaks and transmitting information for remote monitoring of the state of heating mains.

From the prior art there are many technical solutions related to the operation of pipelines, in particular heating mains and are used to detect leaks, coolant flow.

So there is a method for diagnosing a heating main (RF patent No. 2476762), which consists in controlling the flow rate of the coolant. In a known solution, the temperature and flow rate of the coolant are measured in the supply and return pipelines of each heat consumer connected to the heating main. If the temperature of the heat carrier in the supply or return pipeline at any heat consumer rises, and the flow rate of the heat carrier does not change while the temperature of the heat carrier in a similar pipeline decreases at the heat consumer following in the direction of the heat carrier, then on the basis of this, a conclusion is made about the presence of a leak or about unauthorized withdrawal of the heat carrier in the section of the heating main between these heat consumers. The method allows to provide high accuracy of diagnostics of the technical condition of the heating main without the use of additional measuring instruments. However, this method has disadvantages, namely, when measuring the temperature and flow rate of the coolant in the supply and return pipelines of each heat consumer connected to the heating main, it entails large time costs in pipeline diagnostics, since it is required to analyze and compare several systems and readings all heat meters.

A known method for determining the location of a heating main leak (RF patent No. 2566112) consists in the fact that on the controlled section of the heating main in the thermal insulation covering the pipeline with dielectric properties, electrical resistance control devices are installed at the ends on one line of the conductive signal conductor, resistors are installed in series at specified distances, having equal values of electrical resistance exceeding the value of thermal insulation resistance when wet, and the distance to the place of leakage from the device for monitoring electrical resistance is determined by dividing the measured total electrical resistance of the conductive signal conductor by the electrical resistance value of one resistor and multiplying the result by the distance between the resistors. This solution makes it possible to control the state of the insulation with high accuracy and draw a conclusion about the presence of leaks in branched pipelines with thermal insulation. Installation of the system and its operation do not require large expenditures. The disadvantage of this method is the connection of electrical resistance control devices into a single information network, which are also connected to a logical device, which entails the creation of a complex structure of the control method at the stage of laying pipes. Data for all control devices must be entered into a logical device that calculates its location when a leak occurs, the process of determining the location of a leak is complicated by computational steps. Another disadvantage is the inability to obtain measurement results remotely.

The closest technical solution of the same purpose to the claimed invention in terms of the totality of features is the "System for operational remote control of the state of insulation of pipelines with thermal insulation from polyurethane foam, method and device" according to the patent of the Russian Federation No. 2289753.

The known system for operational remote control of the state of insulation of pipelines with thermal insulation includes the main and transit signal conductors in the thermal insulation layer of main pipelines, the main signal conductor in the thermal insulation layer of side branches from the main pipeline, terminals at control points for switching signal conductors and connecting control devices, connecting cables, connecting signal conductors with terminals at control points; signal conductors at break points in the heat-insulating layer of pipelines, for example, in structures; signal conductors of adjacent elements of pipelines between themselves in areas where non-insulated elements of pipelines are installed, for example, shutoff valves; grounding, moreover, the main signal conductor is located in the heat-insulating layer of the pipelines on the right in the direction of fluid supply, the transit one is on the left, and in the side branches from the main pipeline, the main signal conductor is included in the break of the main signal conductor of the main pipeline.

The reasons hindering the achievement of the claimed technical result is the impossibility of wireless transmission of control results to a stationary terminal, the transmission is carried out only to a stationary control device located in the carpet, and also provides for a portable control device that needs to be measured directly on the ground. In addition, the installation of the system is carried out during the construction of pipelines using its constituent components of a high degree of prefabrication, because elements of the system - signal conductors are already built into components of pipelines manufactured by an industrial method.

The purpose of this invention is to develop such a system that would provide a technical result - the possibility of remote automatic monitoring and operation of the integrity of heating pipelines, using a wireless communication channel in any operating elements of the heat supply system, as well as detecting leaks without making significant changes to it, which simplifies operation, expands functionality, allows integration into an existing SODK system.

In the process of analyzing the prior art, including searching through patent documents and scientific and technical sources of information containing information about analogues of the claimed invention, the applicant did not find an analogue characterized by features similar to the essential features of the claimed invention. Therefore, the claimed invention meets the condition of "novelty".

The specified technical result in the implementation of the invention is achieved by the fact that in the system for remote automatic control and operation of pipelines of heating mains using a wireless communication channel containing a ground carpet on which at least one interface converter is installed, which is a module with a programmable board with inputs for connecting signal conductors and a connector for the battery, and also equipped with a connector for connecting an external antenna fixed on the outer casing of the carpet, which provides communication with at least one LoRaWAN wireless base station and with a wired Ethernet interface for communication with a cloud data processing server, and a cloud storage server, except In addition, the interface converter has a memory for storing measured resistance data and remote transmission in automatic mode.

The presence of an interface converter in the system allows it to be implemented in hard-to-reach places, ensures the versatility of the equipment in all monitored areas, thereby reducing equipment costs and maintenance costs, simplifies operation, and its location in the ground carpet allows access to equipment for periodic maintenance, which in turn simplifies operation.

In addition, the interface converter connected to the cable of the connecting signal conductor provides maximum measurement accuracy and further wireless transmission of the received data for processing, which reduces the number of elements in the insulation state measurement circuit, eliminates the need to install terminals.

The presence of a cloud platform in the system provides the possibility of remote automatic monitoring of the state of insulation of pipelines of the existing SODK, simplifies operation, excludes the physical presence of specialists at sections of heating mains to perform measurements, which ultimately expands the functionality of the system.

The inclusion of a cloud data processing server, a cloud data storage server and a base station of the LoRaWAN network into the system provides the ability to remotely automatically control the state of insulation of pipelines of an existing SODK using a wireless communication channel.

Due to the presence of a combination of these features, the system provides the ability to remotely automatically monitor the condition of the insulation of pipelines of the existing SODK (operational remote control system), fine-tune alerts for measuring electrical resistance in controlled sections of the heating main, allows timely detection of malfunctions with devices, battery replacement and transmission of information via a wireless channel connections. In addition, the presence of these features allows you to reduce operating costs, simplify repair work. The system of remote automatic control and operation of pipelines of heating mains can be an integral part of the Platform "Smart City Systems".

The proposed system for remote automatic control and operation of heating pipelines is shown in the block diagram of Fig.1

The system for remote automatic control and operation of pipelines of heating mains (Fig) operates as follows.

An interface converter 2 is installed in the ground carpet 1, which is responsible for measuring the electrical resistance on the lines of the conductive signal conductor of the local heating main (in the proposed system, the resistance on the lines of the conductive signal conductor of the local heating main is designated "Loop"). Interface converter 2 is a module with a programmable board with inputs for connecting a signal conductor and a connector for connecting a battery, enclosed in a plastic case with a degree of protection IP67 (IP67 standard is a high level of resistance to dust and liquid ingress. The first digit is « 6" indicates the case is completely sealed and protected from dust, "7" - indicates a slight resistance of the case to contact with water.). The interface converter is also equipped with a connector for connecting an external antenna, designed to provide communication with the LoRaWAN 3 base station. In addition to electrical resistance, the interface converter measures the temperature parameters inside its module, as well as the battery charge, which can be used to assess the current state of operation of the interface converter, which allows you to identify problems with the device in a timely manner and plan battery replacement. Interface converter 2 is connected to the lines of the signal conductor brought into the ground carpet 1. The control of the heating main is implemented on the basis of measuring the insulation resistance and the signal conductor. According to the insulation resistance, it can be understood whether there are areas in the pipeline with increased moisture content of the insulation, caused either by moisture penetration through the outer polyethylene sheath of the pipeline, or due to leakage of the coolant from the steel pipeline due to corrosion or joint defects. Measurement of resistance in a wide range allows you to control the rate of insulation wetting. Interface converter 2, in addition to measuring the resistance of the signal wire of the local heating main, is capable of measuring the resistance of the signal wire of the main heating main from the boiler room (in the proposed system, the resistance on the lines of the conductive signal conductor of the main heating main is designated "Main"). The interface converter 2 includes a memory for storing measured resistance data and transmitting them remotely in automatic mode. It is also possible to install several interface converters in one carpet. The antenna equipped with the interface converter 2, connected to the connector for an external antenna, is brought out of the carpet 1 and mounted on its body.

Interface converter 2 is connected wirelessly to base station 3 using LoRaWAN technology. This wireless technology operates in frequency bands that do not require licenses and permits from government agencies in many countries (including the Russian Federation), which simplifies the commissioning of base stations.

The LoRaWAN 3 wireless station includes a LoRaWAN module and an antenna for communication with an interface converter that measures electrical resistance, as well as a wired Ethernet 4 interface for communicating over the Internet with a cloud data processing server 5. There can be several LoRaWAN 3 base stations in the heating mains control system, if it is necessary to expand the radius of coverage of the territory. Cloud data server 5 connects to cloud storage server 6.

The measured electrical resistance data is stored and processed on servers and transmitted to the cloud platform 7. The user can access the cloud platform 7 to view and use the data through the remote workstation 8. The remote workstation can be a computer equipped with Internet access. Cloud platform 7 has the ability to view data, build graphs, analyze the received resistance readings, download information, set up an event notification system on the monitored sections of heating mains. Alerts notify users of "emergency" situations based on the following default criteria:

- For "Isolation" if the value is <500 kOhm - this is considered an accident, the user is notified.

- For "Loop" if the value is >100 Ohm - this is considered an accident, an alert is issued.

The user has the ability to set alerts according to the required parameters that are necessary for the operation of the system in controlled areas.

The advantages of this system is the possibility of prompt automatic monitoring of resistance in the controlled sections of heating mains to identify the current state of the insulation. Another important advantage of the proposed system is viewing the current state of the heating mains control system, the ability to remotely view the characteristics of the monitored area, the ability to receive alerts when working with the system, the ability to expand the connection radius of controlled areas by increasing the number of base stations.

At present, the proposed system for remote automatic control and operation of heating pipelines has been introduced in the cities of the region and is successfully operating, which confirms the industrial applicability of the claimed invention.

Claims (1)

A system for remote automatic control and operation of pipelines of heating mains using a wireless communication channel, characterized in that it includes a ground carpet on which at least one interface converter is installed, which is a module with a programmable board with inputs for connecting signal conductors and a connector for a battery, and also equipped with a connector for connecting an external antenna fixed on the outer casing of the carpet, which provides communication with at least one LoRaWAN wireless base station and with a wired Ethernet interface for communication with a cloud data processing server and a cloud storage server, in addition, it has memory for storage of measured resistance data and remote transmission in automatic mode.

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