FR2800858A1 - Nitrogen liquefaction comprises compression to supercritical state and cooking with liquefied natural gas flow, followed by stages of let-down and partial reheating - Google Patents

Abstract

Nitrogen (1) is compressed to a supercritical state and cooled by heat exchange (3) with a liquefied natural gas flow (15). It is then let down in pressure and at least partially liquefied. A fraction (5,14) of the lower pressure nitrogen in gaseous form is then reheated in the heat exchanger, before mixing with nitrogen to be liquefied, upstream of the heat exchanger. An Independent claim is included for corresponding nitrogen liquefaction plant. Preferred Features: Reheated nitrogen is mixed with nitrogen to be compressed and/or is compressed to a pressure below supercritical. The liquefied nitrogen (6) is sub-cooled in a second heat exchanger (7), divided into two fractions. One is reduced in pressure through a valve (45), forming a two-phase mixture sent to a phase separator (50). The liquid fraction is used to subcool the liquid nitrogen in the second heat exchanger. The other fraction is the liquid nitrogen product. The gaseous fraction from the separator is re-heated and mixed with the nitrogen to be liquefied. Some (10) of the liquefied nitrogen is let down to a lower pressure and sent to the first heat exchanger. Only part of the liquefied natural gas is let down in pressure and sent to the first heat exchanger.

Description

The present invention relates to a method and a device for liquefying nitrogen, and in particular to a method and device for liquefying nitrogen using the frigories provided by vaporization of liquefied natural gas (LNG).

JP46016081 discloses a method of vaporizing LNG in which compressed nitrogen cools against a vaporizing LNG flow, the nitrogen is then expanded in a valve and sent to a phase separator.

 EP-A-0304355 discloses an integrated LNG vaporization process with an air separation process. LNG vaporizes in a heat exchanger where two nitrogen flows are cooled at different pressures and one of the nitrogen flows liquefies.

US5141543 also relates to the use of LNG to provide the frigories to a nitrogen liquefaction process. The nitrogen is withdrawn at an intermediate point of the liquefaction exchanger to be compressed before being sent to the exchanger.

According to one object of the invention, there is provided a nitrogen liquefaction process in which the nitrogen is compressed at a supercritical pressure, cooled by heat exchange with a liquefied natural gas flow rate in a first exchanger, expanded to a maximum at a first pressure and at least partially liquefied and a portion of the nitrogen expanded in gaseous form is heated in the first exchanger before being mixed with the nitrogen to be liquefied upstream of the first exchanger.

According to other optional aspects of the invention - the nitrogen which is heated in the first exchanger is mixed with the nitrogen to be compressed and / or compressed at a pressure below the supercritical pressure <B>; </ B> - liquefied nitrogen is subcooled in a second exchanger, divided into two parts, a part is expanded in a valve to a second pressure lower than the first pressure to form a biphasic mixture which is sent into a separator phases whose liquid fraction serves to sub-cool the liquefied nitrogen in the second exchanger and the other part is the production of liquid nitrogen; the gaseous fraction of the phase separator is reheated and mixed with the nitrogen to be liquefied; a part of the liquefied nitrogen is expanded at a second pressure lower than the first pressure and sent to the first exchanger; - only a portion of the liquefied natural gas vaporizes in the first exchanger. According to another aspect of the invention, there is provided a nitrogen liquefaction device comprising a first heat exchanger, means for sending a flow of nitrogen to be liquefied and a flow of liquefied natural gas to the first exchanger, means for isenthalpically expanding the nitrogen to form a gaseous fraction e a liquid fraction and means for sending liquid nitrogen to storage characterized in that it comprises means for heating at least a portion of the gaseous fraction and mixing with the nitrogen to be liquefied upstream of the first exchanger.

 Optionally the device comprises - at least one phase separator and means for sending a gaseous fraction of the (each) phase separator to the first heat exchanger; a first compressor for compressing nitrogen at an intermediate pressure and a second compressor for compressing nitrogen from the intermediate pressure to a supercritical pressure; means for recycling nitrogen gas upstream of the first compressor and / or upstream of the second compressor.

The invention will now be described in more detail with reference to the figure which is a schematic diagram of a device according to the invention.

The pure dry nitrogen 1 is compressed at a pressure higher than that of its critical point in the compressors 20 and 30. It then feeds the main exchanger 3 where it cools and liquefies. After isenthalpic expansion in the valve 4 at medium pressure, it is sent to a phase separator 40. The gas thus produced 5 is returned to the exchanger where it heats up before being mixed with the compressed nitrogen in the compressor 20 to be compressed in the compressor 30. The formed liquid 6 is subcooled in an exchanger 7 before being sent partly to the storage of liquid nitrogen 9. The remainder of the liquid 10 is expanded isenthalpically in the valve 45 to a pressure slightly above atmospheric pressure and sent into a phase separator 50. The liquid portion 12 is vaporized in the exchanger 7 and then mixed with the gas portion 13 to form a flow 14. This flow 14 is heated in the exchanger 3 and is sent to the compressor inlet 20.

The main contribution of frigories is made by a very large flow of liquefied natural gas 15 which passes through the exchanger 3 and heats up against the flow of nitrogen at high pressure 2. The main part of LNG 16, 17 leaves the exchanger 3 at intermediate points being always liquid or partially gaseous. The rest of the LNG 18 is entirely vaporized in the exchanger 3.

To produce 410 tons (day of liquid nitrogen, a flow rate 2 of 22685Nm31h of nitrogen at 35 bara and 15 C is sent to the exchanger 3 and a flow rate of 500m31h of LNG at 7 bara and -157 C.

The flow rate constitutes 6150 Nm 3 / h at a pressure of 5.3 bara and the low pressure nitrogen flow rate 14 is 2500 Nm 3 / h.

The flow of LNG 18 in gaseous form at 13 C is 5850Nm3 / h while the main part of the LNG remains liquid and the flow rates 16 and 17 are respectively at -153.5 C and -142 C.

Claims (10)

<B> CLAIMS </ B> A nitrogen liquefaction process in which the nitrogen (1) is compressed to a supercritical pressure, cooled by heat exchange with a liquefied natural gas flow (15) in a first exchanger (3), expanded to a first pressure and at least partially liquefied and a portion (5,14) of the nitrogen expanded in gaseous form is heated in the first exchanger (3) before being mixed with the nitrogen to be liquefied upstream of the first exchanger. The process of claim 1 wherein the nitrogen which is heated in the first exchanger (3) is mixed with the nitrogen to be compressed and / or compressed to a pressure below the supercritical pressure. 3. Method according to one of the preceding claims wherein liquefied nitrogen (6) is sub-cooled in a second exchanger (7), divided into two parts, a portion is expanded in a valve (45) up to a second pressure lower than the first pressure to form a biphasic mixture which is sent into a phase separator (50) whose liquid fraction serves to sub-cool the liquefied nitrogen in the second exchanger and the other part is the production of liquid nitrogen. 4. The method of claim 3 wherein the gaseous fraction of the phase separator (50) is reheated and mixed with the nitrogen to be liquefied. 5. Method according to one of the preceding claims wherein a portion (10) of the liquefied nitrogen is expanded to a second pressure lower than the first pressure and sent to the first exchanger (3). 6. Method according to one of the preceding claims wherein only a portion of the liquefied natural gas is vaporized in the first exchanger (3). A nitrogen liquefaction device comprising a first heat exchanger (3), means for sending a nitrogen flow to be liquefied and a liquefied natural gas flow rate to the first exchanger, means for isenthalpically expanding the nitrogen to form a gaseous fraction e a liquid fraction and means for sending liquid nitrogen to the storage characterized in that it comprises means for heating at least a portion of the gaseous fraction and mixing it with the nitrogen to be liquefied upstream of the first exchanger. 8. Device according to claim 8 comprising at least one phase separator (40,50) and means for sending a gas fraction of the (each) phase separator to the first heat exchanger (3). 9. Device according to claim 7 or 8 comprising a first compressor (20) for compressing the nitrogen at an intermediate pressure and a second compressor (30) for compressing the nitrogen of the intermediate pressure at a supercritical pressure. 10. Device according to claim 9 comprising means for recycling nitrogen gas upstream of the first compressor (20) and / or upstream of the second compressor (30).