RU198877U1 - Flow-through condensate trap for gas pipeline - Google Patents

Abstract

The proposal relates to the field of the oil and gas production industry, namely to gas transportation for collection of separation, accumulation and removal of liquid contained in the pumped gas, and can be used in the construction and operation of gas supply systems, gas transmission networks, including gas distribution networks. a container for collecting condensate with multidirectional inlet and outlet pipes, a condensate drain pipe with a means of closing it at the upper end and a bypass with shut-off valves. The inlet branch pipe is made downward from the gas pipeline with the inlet to the container above the liquid level, but below the outlet pipe, equipped with an upwardly directed outlet inside the container. The bypass is connected by its ends with the upper part of the tank and the condensate drainage tube above the tank. The inlet branch pipe on the side opposite to the gas pipeline can be equipped with heat-removing fins. The flow-through condensate collector for the gas pipeline allows, while maintaining the quality of gas purification from liquid, significantly reduce the resistance to gas flow. 1 wp f-ly, 1 dwg

Description

The proposal relates to the field of the oil and gas industry, namely to gas transportation for collecting the separation, accumulating and removing the liquid in the pumped gas, and can be used in the construction and operation of gas supply systems, gas transmission networks, including gas distribution networks.

Known plastic condensate collector for a gas pipeline (patent for PM RU No. 193317, IPC F17D 1/02, F16T 1/00, publ. 23.10.2019 Bull. No. 30), including a section of the gas pipeline expanded in diameter, communicated by two branch pipes with a tank located at the bottom for collecting condensate, a condensate drain pipe with a means of closing it at the upper end, hermetically entering from the top of the expanded section of the gas pipeline, passing through a branch pipe located at the entrance to this section, and communicating with the lower part of the condensate collection container, and the container for collecting condensate is made with a volume of at least of the expanded section of the gas pipeline, equipped with successively installed non-blind upper and lower partitions, overlapping more than half of the cross-section of the expanded section, the upper one being installed at its entrance, and the lower one between the branch pipes.

The disadvantages of this device are the complexity of manufacture and high material consumption associated with the presence of a separate container for collecting and draining condensate.

A condensate collector is also known (see http://ifska.ru/archives/34, produced by the branch of LLC Kalugapromstroygaz, Burstroyproekt, Orel), which includes a vertical container for collecting condensate with single-level multidirectional inlet and outlet pipes, a condensate outlet pipe with means of overlapping it at the upper end.

The disadvantages of this condensate collector is low gas purification from liquid (no more than 30%) contained in the gas, which requires more frequent (2 - 3 times compared to the previous analogue) installation of such condensate collectors on the gas pipeline.

The closest in technical terms is an installation for complex gas purification (patent for PM No. 2363881, IPC F17D 1/02, publ. 08/10/2009 Bull. No. 22), including a pressure gas pipeline, a condensate collector, a restriction device, and the condensate collector body is made in the form a horizontal shell, reinforced with stiffening ribs with a diameter significantly larger than the diameter of the main gas pipeline, and is equipped with gas inlet and liquid outlet pipes, inside the condensate collector there is a restriction device made in the form of a throttle washer, a separation grid and a condensate drain pipe, and the pressure gas pipeline is equipped with a bypass and shut-off valves.

The disadvantage of this device is a large pressure drop in the pressure head pipeline due to the presence of a throttle washer and a separation grid, which are hydraulic resistances.

The technical task of the proposed utility model is to create a design of a flow-through condensate collector for a gas pipeline, which, while maintaining the quality of gas purification from liquid, significantly reduces the resistance to gas flow.

The technical problem is solved by a flow-through condensate collector for a gas pipeline, which includes a condensate collection tank with multidirectional inlet and outlet nozzles, a condensate drain pipe with a means of closing it at the upper end and a bypass with shut-off valves.

The novelty is that the inlet pipe is made descending from the gas pipeline with the inlet to the container above the liquid level, but below the outlet pipe equipped with an upward outlet inside the container, while the bypass is connected with its ends to the upper part of the container and the condensate tube above the container.

It is also new that the inlet pipe on the side opposite to the gas pipeline is equipped with heat-removing ribbing.

The drawing shows a diagram of the condensate collector in a partial section.

The flow-through condensate trap for the gas pipeline 1 includes a tank 2 for collecting condensate with multidirectional inlet 3 and outlet 4 nozzles, a condensate drain pipe 5 with a means of shutting it off 6 (valve, tap, etc.) at the upper end and a bypass 7 with shut-off valves 8 (tap , valves, etc.). The inlet nozzle 3 is made descending from the gas pipeline 1 with the inlet 9 into the tank 2 above the liquid level 10, but below the outlet nozzle 4 equipped with an upward outlet 11 inside the tank 11. The bypass 7 is connected with its ends to the upper part of the tank 2 and the condensate tube 5 above the tank 2 The inlet nozzle 3 on the side opposite to the gas pipeline 1 can be equipped with heat-removing fins 12 for cooling at temperatures causing intensive formation of steam from condensate drops (usually above 40-50 ° C).

Structural elements, process connections and seals that did not affect the performance of the condensate collector are not shown in the drawing or are shown conditionally.

The condensate collector works as follows.

In places of the gas pipeline 1, where there is a decrease in the level of the gas pipeline, and / or the temperature drops below the "dew point" (intense condensate precipitation with a decrease in temperature), and there is a threat to get a water seal due to the condensate, which makes it difficult to pump gas through pipeline 1, condensate collectors are installed. To do this, a container 2 for collecting condensate is connected to the rupture of the gas pipeline 1 using the inlet 3 and outlet 4 nozzles. Gas with a vapor content when passing from the gas pipeline 1 to the inlet pipe 3 interacts with its opposite inclined wall, on which, from the collision, vapors of liquid, which are carried with the gas, increase and collect in droplets. This wall of the inlet pipe 3 heats up due to the condensation of liquid vapor and the effect of the gas flow. If there is a threat of a temperature rise of 40 ° C to remove excess heat into the air (when the gas pipeline 1 is located on the ground) or into the ground (when laying the gas pipeline 1 underground), the wall on the side opposite to the gas pipeline is supplied with ribs 12, the area of which is determined in advance in laboratory conditions or empirically. The resulting droplets flow down the inclined inlet pipe into the container 1. Part of the droplets under the action of the gas flow in the inlet pipe 3 evaporates again, sharply reducing the flow temperature and intensifying the formation of condensate from the vapor remaining in the gas. Gas from the inlet 9 of the inlet pipe 3 at an angle from top to bottom enters the container 2, where, interacting with the surface of the liquid, it intensively gives off condensate, which is retained in the liquid due to surface tension. After that, the already previously dried gas rises up in the container 1 and, interacting with the walls of the container 1, continues to give off condensate. From the top of the container 1, the gas is directed through the outlet 11 and the outlet 4 further into the gas pipeline 1. Since the outlet 11 is directed upwards, it is excluded the capture of condensate with the gas flow ascending in the container 2. In this case, the level 10 of the liquid in the tank 2 due to the collection of condensate increases when the maximum permissible level is reached (determined by visual, electronic or similar level gauges). A mobile container with a pump (not shown) is fitted to the condensate trap, the inlet hose 13 of which is connected through the overlap 6 to the condensate pipe 5. Without stopping the work of the gas pipeline 1, open the overlap 6 and by means of a pump through the condensate pipe 5, the liquid is pumped out from the container 2 to the minimum level. Then the pump is turned off, the overlap means 6 is closed, from which the hose 13 is disconnected, and the container with the pump is moved to another condensate collector. Since there are no special hydraulic resistances in the condensate trap, the pressure loss of the gas flow in the tank 2 is not significant.

If it is necessary to replace the condensate outlet tube 5 (for example, due to corrosion) and / or to clean the tank 2 from accumulated dirt and / or sludge. The gas pipeline 1 is closed on both sides (not shown), a mobile container with a pump (not shown) is fitted to the condensate trap, the inlet hose 13 of which is connected to the condensate drainage pipe through the shut-off means 6 5.the shutoff means 6 are opened and pumped out through the condensate drainage pipe 5 liquid from tank 2. In this case, a vacuum is created in tank 2 above the liquid level 10, which prevents the liquid from being pumped out. To equalize the pressure, the pumping is stopped, the liquid is poured from the hose 13 into the mobile container, the shut-off valves 8 are opened, and the air from the hose through the condensate pipe 5 and the bypass 7 enters the container 2, increasing the pressure in it above the level of 10 liquid. In this case, the lighter and / or poisonous gas will not escape into the external space. Then the pumping out of the liquid by the pump through the condensate pipe 5 is continued. The cycles in the tank 2 for equalizing the pressure and pumping out the liquid are repeated until the liquid is completely pumped out of it together with the fine dirt on the bottom of the tank 2. Connection 14 (flange, coupling, etc.) of the condensate drain pipe 5 with the tank 2 is disassembled, removing the tube 5 from tank 2. The condensate tube 5 is replaced and / or the tank 2 is cleaned with special pumps (not shown) from accumulated dirt and / or sludge. After installing the condensate outlet pipe 5 and sealing the connection 14, the gas pipeline 1 is opened on both sides, and the condensate collector operates in the same mode.

A flow-through condensate trap for a gas pipeline allows, while maintaining the quality of gas purification from liquid, significantly reduce the resistance to gas flow.

Claims (2)

1. A flow-through condensate trap for a gas pipeline, including a tank for collecting condensate with multidirectional inlet and outlet pipes, a condensate drain pipe with a means of closing it at the upper end and a bypass with shut-off valves, characterized in that the inlet pipe is made descending from the gas pipeline with the inlet to the container above the level liquid, but below the outlet, equipped with an upwardly directed outlet inside the tank, while the bypass is connected with its ends with the upper part of the tank and with a condensate drain pipe above the tank. 2. A flow-through condensate trap for a gas pipeline according to claim 1, characterized in that the inlet pipe on the side opposite to the gas pipeline is equipped with heat-removing fins.

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