RU147391U1 - INSTALLATION FOR THE DEETHANIZATION OF UNSTABLE GAS CONDENSATE WITH THE POSSIBILITY OF PRELIMINARY DISPAGES - Google Patents

Abstract

1. Installation for deethanization of unstable gas condensate (NGC), containing a deethanization column, two three-phase separators, the output of the first three-phase separator is connected to the inlet of the deethanization column, the first heat exchanger for heating the NGC is installed at the input of the second three-phase separator, the output of which is connected to the column power input deethanization through a second heat exchanger for heating the OGC, while the outputs for the gases of the first and second three-phase separators and deethanization columns are connected to the gas exhaust line eetanizatsii, characterized in that the second heat exchanger for heating NGK represents reboiler type heat exchanger for gases whose output is connected to the discharge line deetanizatsii.2 gases. A plant according to claim 1, characterized in that the bottom part of the deethanization column is connected to a heat-carrier line - hot de-ethanized gas condensate, on which the second and first heat exchangers for heating NGK are installed in series. Installation according to claim 2, characterized in that the coolant line has a bypass parallel to the section with the reboiler type heat exchanger. 4. Installation according to claim 3, characterized in that on the coolant line and on the bypass valve-regulators are installed.

Description

The utility model relates to the field of the gas industry and is an improved way of field preparation for the production of gas condensate deposits.

A known installation for field preparation of gas condensate fluid and deethanization of condensate, which carries out the separation of gas from the inlet and low temperature separation stage, phase separation of the condensate inlet and low temperature separation stages, degassing the condensate and deethanization of the condensate in the stripping distillation column. All the condensate of the inlet separation stage after preliminary degassing and heating in a recuperative heat exchanger is supplied to the middle part of the stripping distillation column as power, the condensate of the low-temperature separation stage is divided into two streams. The first is fed to the top of the stripping distillation column as irrigation, the second to a degasser (RU 2243815 C1, published January 10, 2005).

Closest to the proposed is an installation for deethanization of unstable gas condensate (NTK), which contains a deethanization column, two three-phase separators, the output of the first three-phase separator is connected to the inlet of the deethanization column, the first shell-and-tube heat exchanger for heating the NTK is installed at the input of the second three-phase separator, the output of which connected to the power input of the deethanization column through a second shell-and-tube heat exchanger for heating the NTC, while the outputs for gases of the first and second t phase separators and deethanization columns are connected to the de-ethanization gas exhaust line, and the bottom part of the de-ethanization column is connected to the heat-carrier line - hot de-ethanized gas condensate, on which the second and first heat exchangers for heating the NTC are installed in series. The unit pre-heats NTK extracted from “raw” gas from gas condensate fields; separation of a water-methanol solution with mechanical impurities and preliminary blowing of deethanization gases in buffer tanks; heating the NTK to the required temperature before being fed to the deethanization column; deethanization of NTK in a distillation column of deethanization (RU 2446854 C1, published on March 20, 2011).

A common drawback of the above mentioned installations is the lack of reserve capacities for additional degassing in front of the gas condensate deethanization columns.

During overhauls of gas condensate deethanization plants, it becomes necessary to separately decommission individual process lines. In this case, the load on unstable gas condensate on the threads remaining in operation increases. Accordingly, the vapor phase load of the deethanization columns increases. Due to overload on the vapor phase in the column, the technological mode is violated.

During the failure of the technological regime at the complex gas treatment unit, the methane and ethane content in unstable gas condensate periodically increases, which leads to disruptions in the operation of the gas condensate deethanization unit.

The objective of the utility model is to eliminate disturbances in the operation of the gas condensate deethanization unit caused by an increase in the content of methane and ethane in the NTC.

The technical result of the utility model is to ensure the reduction of methane and ethane content in the NTC supplied to the deethanization column.

The utility model is solved by an installation for deethanization of unstable gas condensate (NTC) containing a deethanization column, two three-phase separators, the output of the first three-phase separator is connected to the irrigation input of the deethanization column, the first heat exchanger for heating the NTC is installed at the input of the second three-phase separator, the output of which is connected to the input supplying the deethanization column through a second heat exchanger for heating the NTC, while the outputs for the gases of the first and second three-phase separators and deethanization columns oedineny with discharge line deethanizer gases, according to the invention wherein a second heat exchanger for heating the STC is a reboiler type heat exchanger for gases whose output is connected to the discharge line deethanizer gases.

In addition, the bottom part of the deethanization column is connected to the coolant line — hot deethanized gas condensate, on which the second and first heat exchangers are installed in series for heating the NTC.

In this case, the heat transfer line has a bypass parallel to the section with the reboiler type heat exchanger, and control valves are installed on the heat transfer line and on the bypass.

Thus, the problem of the utility model is solved by replacing conventional shell-and-tube or plate heat exchangers designed to heat the NTK in front of the deethanization column with a reboiler type heat exchanger with the possibility of partial degassing of the NTK entering its annulus.

The drawing shows a diagram of the proposed installation.

Installation for deethanization of unstable gas condensate (NTC) contains a deethanization column 1, two three-phase separators 2 and 3 (buffer tanks), the inputs of which are connected to the NTK supply line 8, divided into the first and second NTK flows. The output of the first three-phase separator 2 is connected to the inlet of the deethanization column 1. At the input of the second three-phase separator 3, a first plate or shell-and-tube heat exchanger 4 is installed for heating the NTK. The output of the second three-phase separator 3 is connected to the power input of the deethanization column 1 through a second heat exchanger 5 for heating the NTK. The outputs for the gases of the three-phase separators 2 and 3 and the deethanization column 1 are connected to the de-ethanization gas exhaust line 11. The outputs for the water-methanol solution of the three-phase separators 2 and 3 are connected to the line 10 of the removal of the water-methanol solution. The bottom part of the deethanization column 1 is connected to the coolant line 9 — hot deethanized gas condensate, on which the second and first heat exchangers 5 and 4 are sequentially installed for heating the NTC. The second heat exchanger 5 is a reboiler type heat exchanger, the output of which for gases is connected to the de-ethanization gas exhaust line 11.

The coolant line 9 has a bypass parallel to the section with the reboiler type heat exchanger 5, and control valves are installed on the coolant line 9 and on the bypass.

Installation works as follows.

The NTC from the integrated gas treatment unit (UKPG) is divided into two parts. The first stream is fed to the first three-phase separator 2 — a buffer tank for the irrigation of column 2, where a water-methanol solution and some of the deethanization gas are separated from it. Deethanization gases from the three-phase separator 2 are returned via line 11 to the UKPG. NTK from a three-phase separator 2 due to the pressure drop enters the irrigation column 1 deethanization.

The second stream of NTK with UKPG is heated in the heat exchanger 4 and served in the second three-phase separator 3 - buffer capacity of the power supply column 1 deethanization. As a result of the temperature increase in the three-phase separator 3, the residual amount of the salt-containing water-methanol solution is separated from the NTC, and the excess amount of deethanization gases is also blown off. Deethanization gases from buffer tank 3 are returned via line 11 to the gas treatment plant. Unstable gas condensate from the buffer tank 3, due to the pressure difference, enters the reboiler type heat exchanger 5 (reboiler), where it is heated with deethanized gas condensate to the required temperature, is additionally degassed and sent as power to the deethanization column 1. The deethanization gases from the reboiler 5 are discharged through the line 11 at the gas treatment plant.

Column 1 deethanization is a distillation column column type. The heat supply to the deethanization column 1 is provided due to the circulation of part of the deethanized gas condensate by the pump 6 through the fire heater 7.

The deethanization gases from the top of the deethanization column 1 are sent via line 11 to the gas treatment unit.

The deethanized gas condensate from the bottom part of the deethanization column 1 enters through the coolant line 9 for cooling to heat exchangers 5 and 4 and then to the main condensate line.

Using a heat exchanger 5 reboiler type allows you to:

- to carry out preliminary degassing of the NTC during a period of a temporary increase in the load on the column 1 deethanization;

- due to preliminary degassing, stabilize the technological regime at the gas condensate deethanization unit during a period of a temporary increase in the methane and ethane content in unstable gas condensate (failure of the gas treatment plant).

Claims (4)

1. Installation for deethanization of unstable gas condensate (NGC), containing a deethanization column, two three-phase separators, the output of the first three-phase separator is connected to the inlet of the deethanization column, the first heat exchanger for heating the NGC is installed at the input of the second three-phase separator, the output of which is connected to the column power input deethanization through a second heat exchanger for heating the OGC, while the outputs for the gases of the first and second three-phase separators and deethanization columns are connected to the gas exhaust line eetanizatsii, characterized in that the second heat exchanger for heating NGK represents reboiler type heat exchanger for gases whose output is connected to the discharge line deethanizer gases. 2. Installation according to claim 1, characterized in that the bottom part of the deethanization column is connected to a heat-carrier line - hot de-ethanized gas condensate, on which the second and first heat exchangers for heating NGC are installed in series. 3. Installation according to claim 2, characterized in that the coolant line has a bypass parallel to the section with the reboiler type heat exchanger. 4. Installation according to claim 3, characterized in that on the coolant line and on the bypass valves-regulators are installed.

Images