RU2555088C1 - Heated transport pipeline - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: collector with heat-transfer medium bears against outer surface of heated pipeline. Geothermal heat pump is used as heat source for heat-transfer medium. The heat pump contains connecting pipelines, throttles, steam generator, evaporator, three ejectors connected in series, three condensers where the third condenser has heating pipe, three circulating pumps, heat accumulator with collector. Each ejector consists of inlet chamber, nozzle and diffusor. Heat accumulator collector is connected with steam generator via the first circulating pump. Steam from generator is supplied through throttles to nozzles of the first, the second and the third ejectors. Inlet chamber of the first ejector is connected with evaporator outlet via connecting pipeline. The inlet chamber of the second ejector is connected with diffuser of the first ejector via the second circulating pump. The inlet chamber of the third ejector is connected with diffuser of the second ejector via the third circulating pump and the second condenser. Outlets of condensers are connected with evaporator inlet. Ejector exiting steam enters the third condenser and heats heating pipe connected with collector on heating pipeline.

EFFECT: higher pumping efficiency.

1 dwg

Description

The invention relates to pipeline transport and can find application in the transportation of liquids, solutions, suspensions through main pipelines in the petrochemical, chemical, food industries, as well as utilities.

A known pipeline for transporting material, mainly concrete mixture, containing two identical pipe diameters, interconnected by a dielectric pipe with inside it and externally mounted pipes of ferromagnetic material with coils connected to each of the phases of the alternating current source (USSR author's certificate No. 1117824 IPC B65G 53/22, publ. 1984, bull. No. 45).

A well-known pipeline, mainly for heating networks, comprising a metal pipe with a heat-insulating coating of the casting type and an external integral polymer waterproofing sheath, the heat-insulating coating is made of polyurethane (RU 2249754 C2, IPC F16L 59/00, published on 04/10/2002).

The disadvantage of these analogues is the complexity of the design, as well as the inability to change the fluidity of the pumped fluid in places of local resistance (temperature compensators, bends, etc.).

The closest analogue to the claimed invention adopted as a prototype is a transportable heated pipeline containing sections, shutoff valves, an outer insulating layer and a heating element connected to a heat source, composed of separate sections located at the inlet of each section (RU 2250870 C1, IPC B65G 53/52, publ. 04/27/2005).

The disadvantage of the prototype is the complexity of the design of the heating element, as well as the possibility of freezing of pipelines in places of local resistance (temperature compensators, bends of the route, valves, expansion of the cross section of the pipeline, etc.), that is, in places where the speed of pumping liquid through the pipeline decreases.

Due to the fact that in places of local resistance, the pumping speed of the fluid slows down and the temperature drops sharply, this can lead to negative consequences - ruptures, the creation of an emergency.

The objective of the invention is to increase the fluidity of the fluid pumped through the pipeline due to its heating and, accordingly, increasing the speed of pumping in places of local resistance, where there is a decrease.

The technical result is achieved due to the fact that the transport heated pipeline contains sections, shutoff valves, an external insulating layer and a heating element connected to a heat carrier source, but unlike the prototype, the heating element is made in the form of a collector tightly adjacent to the outer surface of the pipeline, as a heat source was used a geothermal heat pump, including connecting pipelines, chokes, a steam generator with a distribution device, vapor spruce, three ejectors, consisting of a receiving chamber, nozzle and diffuser, three capacitors, the third condenser having a heating pipe, three circulation pumps, a heat accumulator with a collector, and the collector output of the heat accumulator through a connecting pipe connected to a steam generator distribution device, the input of which through the first circulation pump and the connecting pipe is connected to the output of the collector of the heat accumulator, the second output of the steam generator through inductors and connecting pipes is connected to the nozzles of the first, second and third ejectors, the receiving chamber of the first ejector through the connecting pipe is connected to the first outlet of the evaporator, the receiving chamber of the second ejector through the connecting pipe, the second circulation pump and the first condenser is connected to the diffuser of the first ejector, the receiving chamber of the third ejector through the connecting the pipeline, the third circulation pump and the second capacitor are connected to the diffuser of the second ejector, the outputs of the first, second and third capacitors through Interconnect lines are connected to the input of the evaporator, the output of the third heating tube condenser through the connecting pipes connected to the inlet manifold of the heating element, the input of the third heating tube condenser through the connecting conduit connected to the outlet manifold of the heating element.

In summer, the average air temperature is positive and ranges from + 10 ° С to + 25 ° С for the middle zone of our country, while the soil temperature will be from + 10 ° С to + 12 ° С, in winter it is negative, from - 10 ° C to -25 ° C, but the temperature of the soil remains positive, decreases from + 3 to + 5 ° C. Thus, in the summer and winter periods of time for the middle zone of our country, the soil temperature is positive, which allows you to use the soil as a heat accumulator.

It is known that in order to increase the vapor pressure in the technique, a jet compressor (ejector) is used. A jet compressor consists of a working nozzle, a receiving chamber, a mixing chamber, a compressor diffuser (Edited by E. Guygo. Technical Thermodynamics. Leningrad: University of Leningrad. - 1984, p. 199).

In the mixing chamber and the diffuser of the jet ejector, the pressure of the ejected vapor-air mixture increases, while its temperature increases. This principle is based on the action of a heat pump - a device for transferring thermal energy from a source of low potential thermal energy to a consumer with a higher temperature.

The invention proposes to use a sequential circuit for switching on three jet ejectors, respectively providing a pressure p1 <p2 <p3 after each of the diffusers of the ejectors.

In this case, the degree of compression of the vapor-air medium in a three-stage sequential circuit for switching on ejectors is determined as the ratio of the pressure in the diffuser of the ejector of the third stage to the pressure in the diffuser of the ejector of the first stage

It is known that in proportion to the increase in pressure, the temperature of the vapor-air medium increases. Increasing the pressure of the ejected flow without the expense of mechanical energy is the main one for a jet compressor.

For example, for a steam-air mixture consisting of technical alcohol entering the ejector of the first stage, the pressure p1 = 0.04 atm. After the diffuser of the ejector of the second stage, the pressure is p2 = 0.16 atm, after the diffuser of the ejector of the third stage is p3 = 0.36 atm. Thus, the total compression ratio developed by the three-stage sequential circuit for switching on the ejectors is p3 / p1 = 9. If the temperature of the vapor-air mixture in the diffuser of the first ejector is 5 ° C, then in the diffuser of the third ejector it should be 5 ° Cx9 = 45 ° C. Given the heat loss in the third condenser, (k = 0.8-0.9), the temperature of the collector of the heating element used for the heated pipeline is 36-40.5 ° C.

The scheme of the transport heated pipeline is shown in the drawing.

The transported heated pipeline contains a section 1, which is located between the shut-off valves 2, the outer insulating layer 3 and the heating element 4 in the form of a collector with coils 6 tightly adjacent to each other and to the outer surface of the pipeline through which the coolant passes from the heat pump 5.

The heat carrier source is a geothermal heat pump 5. It contains chokes 7, a steam generator 8, an evaporator 9, three ejectors (10, 12, 14) and three condensers (11, 13, 15), each of the ejectors consists of a receiving chamber, a nozzle and diffuser, the third condenser includes a heating pipe 27. Further, the heat pump also includes the first ejector 10, the first capacitor 11, the second ejector 12, the second capacitor 13, the third ejector 14, the third condenser 15, circulation pumps 16, a heat accumulator 17 with a collector 18, heat collector 18 output pa through the connecting pipe 19 is connected to the switchgear 20 of the steam generator 8, the input of which through the circulation pump 16 and the connecting pipe is connected to the output of the heat accumulator 17, the second output of the steam generator 8 through the chokes and connecting pipes is connected to the nozzles 21 of the first, second and third ejectors , the receiving chamber 22 of the first ejector through the connecting pipe is connected to the first outlet of the evaporator, the receiving chamber of the second ejector 23 through the connecting pipe, circulation the pump and the first condenser are connected to the diffuser 24 of the first ejector, the receiving chamber 25 of the third ejector through the connecting pipe, the circulation pump and the second condenser are connected to the diffuser 26 of the second ejector, the outputs of the first, second and third condensers are connected through the connecting pipes to the input of the evaporator, the heating output the pipe 27 of the third capacitor through the connecting pipe is connected to the input of the collector 6 of the heating element 4, the input of the heating pipe of the third capacitor 27 through Yelnia conduit connected to the outlet header 6 of the heating element.

Transport heated pipeline works as follows.

Before work, the steam generator 8 and the evaporator 9 are filled with technical alcohol.

When the circulation pump 16 is turned on, technical alcohol from the collector of the heat accumulator 17 is pumped to the switchgear of the steam generator 20. In the steam generator, part of the technical alcohol is vaporized, alcohol vapors are formed (working steam), and the remaining alcohol is circulated by the circulation pump 16 to the collector 18 of the heat accumulator 17 The generated working steam through connecting pipelines and chokes 7, reducing its pressure, enters the nozzle 21 of the first ejector 10, the second ejector 12, the third ejector 14 and puddles the carrier with colder alcohol vapors sucked from the evaporator 9. In this case, the working and ejected cold vapor condenses in the first, second and third condensers 11, 13, 15, and the remaining alcohol vapors are removed through the connecting pipes to the evaporator 9. In the diffuser of the first ejector 10 the pressure of the mixture increases, in the diffuser of the second ejector 12, the pressure of the mixture increases even in the diffuser of the third ejector 15, the vapor pressure increases even more. In this case, the vapor pressure of the alcohol reaches a maximum value. With increasing pressure, the temperature of the alcohol vapor increases. In this case, sufficiently heated alcohol vapors enter the input of the third condenser 15 and heat the coolant in the heating pipe 27 of the third condenser. The coolant through the connecting pipeline enters the manifold 6 of the heating element 4 in contact with the surface of the pipeline, and heats the pipeline in areas located in front of the local resistances of the heated pipeline.

The use of a heated transport pipeline allows to increase the temperature of the transported fluid in places of local resistance of the pipeline, to avoid an emergency, to increase the productivity of pumping fluid by 20-25%.

Claims (1)

Heated transport pipeline containing sections, shutoff valves, an external insulating layer and a heating element connected to a heat carrier source, characterized in that the heating element consists of a collector with a heat carrier that is closely adjacent to the outer surface of the pipeline, using a geothermal heat source as a heat source a pump including connecting pipelines, chokes, a steam generator with a switchgear, an evaporator, three ejectors, consisting of a receiving chamber, a nozzle and a diffuser, three condensers, the third condenser having a heating pipe, three circulation pumps, a heat accumulator with a collector, the output of the heat accumulator collector through a connecting pipe connected to a steam generator switchgear, the input of which is through the first circulation pump and a connecting pipe connected to the output of the collector of the heat accumulator, the second output of the steam generator through the inductors and connecting pipelines is connected to the nozzles of the first, the second and third ejectors, the receiving chamber of the first ejector through the connecting pipe is connected to the first outlet of the evaporator, the receiving chamber of the second ejector through the connecting pipe, the second circulation pump and the first condenser is connected to the diffuser of the first ejector, the receiving chamber of the third ejector through the connecting pipe, the third circulation pump and the second capacitor is connected to the diffuser of the second ejector, the output of the first, second and third capacitors through connecting pipelines with are connected to the evaporator inlet, the output of the heating pipe of the third condenser through the connecting pipe is connected to the input of the collector of the heating element, the input of the heating pipe of the third condenser through the connecting pipe is connected to the output of the collector of the heating element.