RU2623015C1 - Gas-distributing station - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: gas-distributing station contains a control unit, a process unit with high and low pressure gas line, a condensate tank, an ejector, a vortex tube, a heat exchanger, a control unit is equipped with an outdoor temperature sensor and a vortex tube hot flow-rate regulator, the outer surface of the condensate tank is covered with a heat-insulating and heat-accumulating material. Condensate extractor includes a case with a lid and a conical bottom connected to the condensate tank and is provided with a deflecting baffle which is designed with a coating, obtained by a ion-plasma method, a glass-like nano-shaped film of tantalum oxide from the side of the input nozzle of cold-flow from the vortex tube, besides, the deflecting baffle is connected to the lid and is located between the input and output nozzles of the cold flow.

EFFECT: increasing operating efficiency of the plant during long-term exploitation.

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Description

The invention relates to gas technology, in particular to gas distribution stations for reducing gas pressure in a gas pipeline.

A known gas distribution station (see RF patent No. 2428621, IPC F17D 1/04, publ. September 10, 2011. Bull. No. 25), comprising a control unit, a process unit with a high and low pressure gas pipeline, a condensate collection tank connected to a high gas pipeline pressure and through a shut-off element with a low pressure gas pipeline, an ejector, a vortex tube mounted on a high pressure gas pipeline, a heat exchanger connected to the outlet of the hot stream of the vortex tube, and the outlet of its cold stream is connected to the condensate drain, while the control unit I am equipped with an outside air temperature sensor and a vortex tube hot flow flow regulator located at the inlet of the ejector, and the heat exchanger is plate-shaped and located on the recirculation loop of the heating system and connected to the ejector inlet with its outlet, while the outlet of the ejector is connected to the low pressure gas pipeline, and it the mixing chamber is connected to a steam trap.

The disadvantage is the reduction of the normalized parameters of the combustion process due to incomplete removal of the excess air present in natural gas at low temperatures, which is due to the violation of heat and mass transfer in the changing temperature regime of the soil as the environment for the condensate collection tank.

A known gas distribution station (see, RF patent No. 2544404, IPC F17D 1/04, published March 20, 2015.) comprising a control unit, a process unit with a high and low pressure gas pipeline, a condensate collection tank connected to the high pressure gas pipeline and through a shut-off element with a low pressure gas pipeline, an ejector, a vortex tube mounted on a high pressure gas pipeline, a heat exchanger connected to the outlet of the hot stream of the vortex tube, and the outlet of its cold stream is connected to the steam trap, and the control unit is provided the outside temperature sensor and the vortex tube hot flow rate controller located at the inlet of the ejector, and the heat exchanger is plate-shaped and located on the recirculation circuit of the heating system and is connected to the ejector inlet with its outlet, while the outlet of the ejector is connected to the low pressure gas pipeline and its mixing chamber connected to a steam trap, and the outer surface of the condensate collecting tank is covered with heat-insulating and heat-accumulating material, made in the form of beams ies thin basalt fibers arranged vertically.

The disadvantage is the decrease in the efficiency of the gas distribution station during long-term operation due to the ingress of fine droplet-like particles of a cold vortex tube stream into the low-pressure line and further to the consumer, which reduces the calorific value of natural gas on household equipment.

The technical task of the invention is to maintain normalized thermal parameters for the calorific value of natural gas during long-term operation by eliminating the penetration of finely divided droplet-like particles into the low-pressure line by increasing the efficiency of their separation in the steam trap due to the performance of the reflective partition with a coating obtained by the ion-plasma method, a glass-like nano-shaped tantalum oxide film on the side of the cold flow inlets from the vortex tube.

The technical result is achieved by the fact that the gas distribution station comprises a control unit, a process unit with a high and low pressure gas pipeline, a condensate collection tank connected to the high pressure gas pipeline and through a shut-off element with a low pressure gas pipeline, an ejector, a vortex tube mounted on the high pressure gas pipeline, a heat exchanger connected to the outlet of the hot stream of the vortex tube, and the outlet of its cold stream is connected to the steam trap, while the control unit is equipped with a sensor t outside air temperature and a vortex tube hot flow regulator located at the inlet of the ejector, and the heat exchanger is plate-shaped and located on the recirculation circuit of the heating system and is connected to the ejector inlet with its outlet, while the outlet of the ejector is connected to the low pressure gas pipeline and its mixing chamber is connected with a steam trap, and the outer surface of the condensate collection tank is covered with heat-insulating and heat-accumulating material, made in the form of elongated thin beams fibers of basalt arranged vertically, while the steam trap includes a housing with a lid and a conical bottom connected to the condensate collection tank, and is equipped with a reflective partition, which is made with a coating obtained by the ion-plasma method, a glass-like nano-shaped film of tantalum oxide from the side of the input pipe cold flow from the vortex tube, in addition, the baffle plate is connected to the lid and is located between the cold flow inlet and outlet nozzles.

Figure 1 presents a schematic diagram of a gas distribution station; figure 2 - the outer surface of the condensate collection tank, covered with heat insulating and heat-accumulating material, made in the form of bundles of elongated thin fibers of basalt, figure 3 - condensate drain with a reflective partition, figure 4 - section of the reflective partition coated with a glass-like nano-like film from tantalum oxide.

The gas distribution station comprises a control unit 1, a process unit 2 with high pressure gas lines 3 and low pressure 4 and a condensate collection tank 5 connected to the high pressure gas pipe 3, while the condensate collection tank 5 is additionally connected through a shut-off member 7 to the low pressure gas pipe 4. In addition, the high pressure gas pipeline 3 is connected to the gas cavity 6 in the condensate collecting tank 5 through a steam trap 8 and a valve 9. In the communication line, the control unit 1 and the condensate collecting tank 5 have a sensor level 10, the crane 11 communicates with the gas pipeline the gas cavity 6 with the atmosphere. A vortex tube 12 is installed on the high pressure gas pipeline 3, its cold flow outlet 13 is connected to a steam trap 8, and its hot flow outlet 14 is connected to an inlet 15 of a plate heat exchanger 16 located in the recirculation circuit 17 of the heating system 18 of the gas distribution station 19. The outlet 20 of the heat exchanger 16 is connected to the inlet 21 of the ejector 22, while the outlet 23 of the ejector 22 is connected to a low pressure gas pipeline 4, and its mixing chamber 24 is connected to a steam trap 8. The control unit 1 is equipped with an outside temperature sensor 25 and a swirl flow control unit 26 pipe 12 located at the inlet 21 of the ejector 22, and to increase the amount of heat given off by the heat exchanger 16 to the heating system 18 of the room 19 of the gas distribution station, it is made lamellar, as "having the highest coefficient heat transfer agent for heat exchange between a heating gas coolant (hot natural gas stream from a vortex tube 12) and a heated liquid coolant (heating system water 18). In terms of heat and energy coefficient, plate heat exchangers are most effective compared to other conventional heat exchangers for pressures up to 1 MPa and working medium temperatures up to 140-150 ° C and can replace all types of shell-and-tube, high-speed and plate constructions of a heat supply system ”(see, for example, pp. 212 and 219 Kovalenko A.N., Glushkov A.F. Heat exchangers with intensification of heat transfer. - M.: Energoatomizdat 1986. 240 p.).

The outer surface 27 of the condensate collection tank 5 is covered with heat-insulating and heat-accumulating material made in the form of bundles of elongated thin fibers of basalt 28 arranged vertically.

The steam trap 8 includes a housing 29 with a cover 30 and a conical bottom 31 connected through a tap 9 to a condensate collecting tank 5. The steam trap 5 is equipped with a reflective wall 32, which is coated with a glass-like nano-like film of tantalum oxide 33 from the side of the cold flow inlet port 34 13 of the vortex tube 12. In addition, the baffle 32 is connected to the cover 30 and is located between the cold flow input pipe 34 from the vortex pipe 12 and its pipe outlet 35 from the condensate drain body 29 8.

Gas distribution station operates as follows.

Natural gas is always saturated with vaporous and finely dispersed moisture that condenses during cooling and transportation, the concentration of which depends significantly on the field (gas production), which leads not only to the corrosion of gas pipelines, but also reduces the heat of combustion when using natural gas as a source of thermal energy (see , for example, p. 33. Kyazimov K.G., Gusev V.E. Design and operation of gas facilities. - M.: Publishing Center "Academy", 2004-384 pp. ill.)

Therefore, the separation of finely dispersed moisture from the cold stream coming from the outlet 13 of the vortex tube 12 into the condensate drain 8 should help to prevent the formation of droplet-like particles in the mixing chamber 24 of the ejector 22 and further into the low pressure gas pipeline 4.

However, when a cold stream saturated with finely dispersed moisture comes into contact with a reflective baffle 32, on its surface, on the side of the cold flow inlet pipe 34 from the outlet 13 of the vortex tube 12, condensation droplets stick, which coagulate and coarsen to form a condensate film, which, due to the viscous friction with the material of the baffle plate flows into the conical bottom for subsequent flow through the valve 9 into the condensate collection tank 5. The condensate film drains under the influence of the traction force tin plate and the viscous drag of the adhering condensate film (see, Altshul AD, et al. Hydraulics and aerodynamics M .: Stroyizdat, 1987-414 pp. ill.) leads to the fact that the condensate film “hangs” between the lower part of the baffle plate 32 and the hole in the conical bottom 31 of the housing 29, connected through a tap 9 to the condensate collecting tank 5. In this case, the cold stream in the steam trap 8, bending around the baffle plate 32 when moving from the input pipe 34 to the output pipe 35, breaks the slowly moving con a densate film onto a lot of fine particles, translating into a state of "wandering" (see, for example, Sedov A.I. Continuum mechanics. - M .: publ. "Subsoil" 1970-537 pp. ill.), it is saturated with them and enters the mixing chamber 24 of the ejector 22 and then into the low pressure gas pipeline for supplying the consumer with a subsequent decrease in the calorific value when using natural gas as a source of thermal energy. To eliminate the sticking of fine particles of moisture on the surface of the reflective partition 32, it is performed with a coating obtained by the ion-plasma method, a glass-like nano-shaped film of tantalum oxide from the side of the cold flow inlet pipe 34 from the vortex tube 12. As a result, a cold stream saturated with fine moisture entering from the pipe 34, is in contact with a glass-like nano-like film of tantalum oxide 33. Then, liquid droplets, due to the absence of viscous friction, slide without coagulation and coarsening, and accordingly without the formation of a condensate film under the action of gravity with the fastest descent (see, for example, Litvinova V.A., Savruk E.N. Nanosized films tantalum oxide obtained by the ion-plasma method // Proceedings of the regional scientific-practical conference "Modern problems and achievements of agricultural science in animal husbandry, crop production and the economy." - Tomsk: TSHI NSAU. - Issue 12. - 2010 - p.299- 301.) enter conic nd the bottom 31 of the body 29 of the steam trap 8, and then through the valve 9 into the condensate collecting container 5. Therefore, in the low-pressure gas outlet 4 respectively and the consumer receives natural gas without moisture fine droplet, providing the normalized heat of combustion when receiving heat energy. When negative outside temperatures increase, the depth of soil freezing also increases (see, for example, SNiP 2.01.01-83 Construction Climatology and Geophysics. - M .: Stroyizdat. 1982), which leads to a change in the temperature regime of moisture entering the condensate collection tank 5 , the amount of which decreases until it is completely stopped due to freezing of the outlet of the pipeline from the tap 9 of the steam trap 8. In addition, in the gas cavity 6, the external surface of the condensate collecting tank 5 in contact with freezing soil, the heat and mass transfer process is disturbed (see, for example, Osipova V.L. Heat Transfer. - M .: 1980) and crystallization of moisture and components associated with natural gas are observed, which also leads to a deterioration in the operating conditions of the gas distribution station. When covering the outer surface 27 of the condensate collection tank 5 with heat-insulating and heat-accumulating material, made in the form of bundles of elongated thin basalt fibers 28, arranged vertically, the body of the condensate collection tank 5 is insulated from freezing soil, which eliminates heat loss while maintaining a given temperature regime of moisture through the pipeline from the steam trap 8 through the valve 9. The location on the outer surface of 27 elongated thin fibers 28 of basalt, located vertically, when heat enters the gas cavity 6 with the heat of the condensation process, it accumulates heat, starting from the lower level of the body of the condensate collecting tank 5 and to its upper level, i.e. to the junction of pipelines with taps 7, 9 and 11, as well as with a level sensor 10 (see, for example, Fibrous materials from basalts of Ukraine. - Kiev: Technics. 1971, 76 pp.). As a result, in the gas cavity 6, the optimal conditions for heat transfer of the condensing mass of the associated components of natural gas are observed under changing weather and climate operating conditions of the gas distribution station.

Natural gas through the high pressure gas pipeline 3 enters the room 9 of the gas distribution station to the technological unit 2 to regulate the gas pressure, and the pressure regulators operate at a sufficiently high (from 3-5 and more times) differential pressure between the gas pipelines of high pressure 3 and low pressure 4 with unclaimed repayment of excess energy (see. Industrial gas equipment. Handbook. - Saratov: Gazovik, 2002. 624 p.).

To use the energy of the gas moving in gas pipelines 3 and 4, a vortex tube is used as a partial absorber of overpressure, and its hot stream is used as a heat source in the heating system of room 19. In process unit 2, natural gas from the high pressure gas pipeline 3 is sent to the vortex pipe 12 where, as a result of thermodynamic separation, a hot stream with a temperature of about 100 ° C is divided into peripheral high-pressure (see, for example, Merkulov A.P. The vortex effect and its application in industry. Kui yshev, 1969. 369 pp.) and a cold low pressure stream having a temperature below the temperature of the gas entering the vortex tube 12.

The hot stream from the outlet 14 of the vortex tube 12, which is a heat source, is directed to the input of the flow regulator 26 located at the inlet 21 of the ejector 22 and connected to the inlet 15 of the plate heat exchanger 16. Depending on the ambient temperature at negative outside temperatures recorded by the temperature sensor 25 outdoor air, the control unit 1 gives a command for full or partial receipt through the flow regulator 26 of the hot stream from the vortex tube 12 to the input 15 of the plate heat exchanger 16, laid on the recirculation loop 17 of the heating system 18 of the room 19 of the gas distribution station. After heating the water of the heating system 18, the hot stream partially cooled to 40-50 ° C from the outlet 20 of the plate heat exchanger 16 enters the inlet 21 of the ejector 22. When the partial flow of hot stream from the vortex tube 12 to the inlet 15 of the plate heat exchanger 16 when the outside temperature is negative It does not require the complete transfer of thermal energy to the heating system 18 of the room 19 from the vortex tube 12, the hot stream arrives at the inlet 21 of the ejector both from the outlet 14 and from the outlet 20 of the plate heat exchanger 16.

A cold gas stream with condensate obtained both during the cooling of vaporous moisture during thermodynamic separation of the gas and associated moving gas through a high pressure gas pipeline 3 passes through a steam trap 8, where condensate is taken and subsequently flows by gravity through a valve 9 through a pipeline into a collection tank condensate 5. When filling the condensate collection tank 5 to a certain level (for example, 0.75 volume) from the level sensor 10, a signal is sent to the control unit 1 about the need to empty the collection tank condensate 5. To empty the condensate collection tank 5, the valve 9 closes and the shut-off valve 7 opens. The gas located in the condensate collection tank 5 enters the low pressure gas pipe 4, and thereby the pressure decreases in the condensate collection tank 5. This allows the condensate in the condensate collection tank 5 to be pumped to a pick-up device, for example to a tank truck, by shutting off the shut-off valve 7 and opening the valve 9.

The cold gas stream purified from condensate in the condensate drain 8 with a pressure lower than the gas pressure at the inlet of the vortex tube 12 enters the mixing chamber 24 of the ejector 22, where it is mixed with a stream having a higher and / or partially cooled stream in the plate heat exchanger 16 having a higher pressure than a cold stream. Mixing with hot and / or partially cooled hot and cold streams before entering the ejector 22 from the outlet 23 into the low pressure gas pipeline 4 provides a gas stream with a temperature that eliminates the appearance of frost, and especially the possibility of freezing of condensed moisture. The use of the ejector 22 not only prevents the loss of gas used as a heat source, but also prevents freezing during throttling.

The originality of the invention to maintain normalized parameters in terms of calorific value is achieved by eliminating the arrival of heat-dispersed droplet-like particles to heat sources through a low pressure gas pipeline by supplying a condensate trap with a reflective baffle made with a glass-like tantalum oxide film obtained by the ion-plasma method.

Claims (1)

A gas distribution station comprising a control unit, a process unit with a high and low pressure gas pipeline, a condensate collection tank connected to the high pressure gas pipeline and through a shut-off element with a low pressure gas pipeline, an ejector, a vortex tube mounted on the high pressure gas pipeline, a heat exchanger connected to the outlet the hot stream of the vortex tube, and the outlet of its cold stream is connected to a steam trap, and the control unit is equipped with an outdoor temperature sensor and a regulator the flow rate of the hot stream of the vortex tube located at the inlet of the ejector, and the heat exchanger is plate-shaped and located on the recirculation circuit of the heating system and is connected with the outlet of the ejector inlet, while the outlet of the ejector is connected to the low pressure gas pipeline, and its mixing chamber is connected to the condensate drain, the outer the surface of the condensate collection tank is covered with heat-insulating and heat-accumulating material, made in the form of bundles of elongated thin basalt fibers, located vertically flax, characterized in that the condensate trap includes a housing with a lid and a conical bottom connected to the condensate collecting tank, and is equipped with a reflective partition, which is made with a coating obtained by the ion-plasma method, a glass-like nano-shaped film of tantalum oxide from the side of the cold flow inlet vortex tube, in addition, the baffle plate is connected to the lid and is located between the inlet and outlet ports of the cold stream.

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