WO2018078249A1 - Method for cryogenically separating a mixture of hydrogen and carbon monoxide - Google Patents

Abstract

In a method for cryogenically separating a mixture of hydrogen and carbon monoxide, the mixture is cooled in a heat exchanger (E) and then separated by partial condensation before being sent to a stripping column, a gas flow rich in nitrogen (71) is cooled in the heat exchanger, at least one part of the gas flow rich in cooled nitrogen is released at the cold end of the exchanger, at least one part thereof is expanded, at least one part of the gas flow rich in nitrogen is liquefied, the at least one liquefied part is vaporised and is heated before at least one part is extracted from it as a gaseous product rich in nitrogen (84).

Description

 METHOD FOR CRYOGENIC SEPARATION OF A HYDROGEN MIXTURE

 The present invention relates to a method and apparatus for the cryogenic separation of a mixture of hydrogen and carbon monoxide. The mixture may also comprise nitrogen and / or methane and / or argon.

 The production units for carbon monoxide and hydrogen can be separated into two parts:

 - Generation of the synthesis gas (mixture containing H2 and CO and at least one of the following components CH4, CO2, Ar and N2). Among the various synthetic gas production industries, the one based on coal gasification seems to develop more and more particularly in countries rich in coal deposits such as China. The partial oxidation process of natural gas can also be interesting for the production of CO alone or with low H2 / CO production ratios. Another way is steam reforming.

 - purification of the synthesis gas. We find :

 a washing unit with a liquid solvent to eliminate most of the acid gases contained in the synthesis gas

 an adsorbent bed purification unit.

 a cryogenic separation unit known as a cold box for the production of

CO.

 In the case where the synthesis gas is produced from coal gasification, generally the acid gas removal unit comprises a methanol wash process which requires a low pressure nitrogen gas flow as the stripping gas. . This nitrogen is generally produced by an apparatus for separating air, for example by cryogenic distillation, or is available at medium pressure and then is expanded in a valve before feeding the stripping column. It is known from US2009 / 0191113 to use a nitrogen flow rate as the gas sent to the bottom of a column fed at the top with methanol containing ammonia from a methanol washing unit. The nitrogen exits the ammonia-enriched column head and the tank methanol which is purified to ammonia can be returned to the washing unit.

On the other hand, the cryogenic separation unit generally comprises a CO compressor that provides the separation energy where part of the high pressure CO is cooled, condensed, then relaxed and vaporized in the exchange line before recompression in the CO cycle compressor.

 It is known from EP-A-0677483 to separate a synthesis gas in a phase separator and then to send the liquid phase separator head of a depletion column. The top condenser of the exhaustion column is cooled by a closed circuit of nitrogen gas.

 The invention uses the expansion of the medium pressure nitrogen necessary to have the stripping gas at the right pressure in the cryogenic separation unit in order to reduce the compression energy of the CO cycle or to completely replace it.

The liquefied nitrogen is expanded in a Joule-Thomson valve, which makes it possible either to reduce the flow rate of the CO cycle, or to reduce the number of stages of the compressor CO or to replace it completely.

 The scheme may also include the expansion of a portion of the medium pressure nitrogen in a flash turbine.

 According to one aspect of the invention, there is provided a process for the cryogenic separation of a mixture of hydrogen and carbon monoxide and optionally methane and / or nitrogen and / or argon in which:

 i) The mixture is cooled in a heat exchanger by introducing it to the hot end thereof, partially condensed and sent to a first phase separator to produce a hydrogen-enriched gas and a hydrogen-depleted liquid,

 ii) the hydrogen-depleted liquid is sent at least partly at the head of a depletion column, operating at a pressure between 5 and 25 bar abs, after expansion in a valve,

 iii) The hydrogen-enriched gas is reheated in the heat exchanger, possibly without having been expanded or separated and possibly not recycled to the synthesis gas

 iv) at least a portion of the bottom liquid of the exhaust column vaporizes at least partially in the heat exchanger and optionally warms up to the hot end of the heat exchanger to form a gas,

 v) The overhead gas of the depletion column is reheated in the heat exchanger optionally without having been expanded or separated and possibly not recycled to the synthesis gas,

(vi) A carbon monoxide enriched product is derived from at least a portion of the bottoms liquid of the depletion column and vii) A nitrogen-rich gas flow is cooled in the heat exchanger by introducing it at the hot end thereof, leaving at least a portion of the cooled nitrogen-rich gas flow at the cold end thereof, and in at least a part of it, liquefies at least a portion of the nitrogen-rich gas flow, vaporizes less of a liquefied portion of Pau, is heated, the heating takes place at least partially in the heat exchanger before extracting at least a portion as a nitrogen-rich gaseous product and the nitrogen-rich gaseous product is fed to a stripping column as a stripping gas.

 According to other optional aspects:

 at least a portion of the liquefied nitrogen-rich gas is vaporized in the heat exchanger.

 - Part of the cooled nitrogen gas is expanded in the heat exchanger in a turbine.

 the gas rich in nitrogen and the gas rich in liquefied nitrogen are not separated by distillation.

 the mixture contains methane and at least a portion of the bottoms liquid from the exhaustion column is sent to a separation column to produce a carbon monoxide enriched gas and a methane enriched liquid and at least a portion of the The liquefied nitrogen is vaporized in a head condenser of the separation column.

 all the nitrogen cooled to the cold end of the exchanger liquefies and then vaporizes in the overhead condenser.

 - The gaseous product rich in nitrogen is sent to the bottom of a column fed at the top by a flow containing methane! and ammonia, in order to produce ammonia-purified methanol at the bottom of the column,

 the mixture is treated upstream of stage i) by the methanol washing process. - The mixture warms the tank of the exhaust column and, if necessary, the tank of the separation column upstream of the first phase separator.

 - Hydrogen and carbon monoxide are major components of the mixture

 the nitrogen gas comes from an air separation apparatus and / or a nitrogen gas line

 all the liquid from the bottom of the exhaustion column is sent to the heat exchanger so that it vaporises without having pressurized it,

the synthesis gas is separated in a single phase separator upstream of the exhaustion column the depletion column is a column equipped with trays or packings

- the first phase separator and, where appropriate, any other phase separator contains neither packings nor trays

 the synthesis gas contains methane and a part of the liquid from the bottom of the exhaustion column is sent to a separation column to produce a gas enriched with carbon monoxide and a liquid enriched in methane,

 all the carbon monoxide enriched gas is reheated in the heat exchanger for use as a product.

 - no part of the carbon monoxide enriched gas is compressed and returned to the process

 a portion of the carbon monoxide enriched gas is compressed and returned to the process

 the hydrogen enriched gas contains at least 20 mol% of carbon monoxide, or even at least 25 mol% of carbon monoxide.

 the hydrogen enriched gas is fed as a feed gas to a methanol production unit.

 the gas enriched with carbon monoxide is produced with a yield of at most 80%, or even at most 75%.

 - The method does not include a step of compressing a fluid except possibly the mixture upstream of step i).

 - The mixture warms the tank of the exhaust column and, if necessary, the tank of the separation column upstream of the first phase separator.

According to another aspect of the invention, there is provided an apparatus for separating a mixture containing hydrogen, carbon monoxide and optionally methane and / or nitrogen and / or argon comprising heat exchanger, a first phase separator, a depletion column, means for sending the synthesis gas to cool in the heat exchanger, means for sending the partially condensed synthesis gas to the first phase separator to produce a hydrogen-enriched gas and a hydrogen-depleted liquid, means for removing the hydrogen-enriched gas from the apparatus after reheating in the heat exchanger and without having expanded, separated or recycled with the synthesis gas, means for sending the hydrogen depleted liquid at least partly to the top of the depletion column after expansion in a valve, means for removing a top gas from the depletion column of the apparatus after I'échangeur heating in heat and without having relaxes or separated, means for sending the at least a portion of the bottom liquid of the stripping column is at least partially vaporized in the heat exchanger and optionally heated to the hot end of the heat exchanger to form a gas, means for deriving a gas enriched with at least a portion of the bottoms liquid from the exhaustion column, means for sending nitrogen gas to cool in the heat exchanger to the cold end, means for heating the chilled nitrogen gas to the end heat in the heat exchanger and means to send heated nitrogen to a stripping column to serve as a stripping gas.

 According to other optional aspects, the apparatus comprises:

 means for sending all the liquid from the bottom of the exhaustion column to

The heat exchanger for vaporizing there, without means of pressurization between the tank of the column of exhaustion and the exchanger of heat.

 means for sending a portion of the bottoms liquid from the exhaustion column to a separation column to produce a carbon monoxide enriched gas and a methane-enriched liquid.

 a separation column for producing a gas enriched with carbon monoxide and a liquid enriched in methane

 means for sending all the carbon monoxide enriched gas is reheated in the heat exchanger to serve as a product.

 means for sending the hydrogen-enriched gas as feed gas to a methanol production unit.

 no means of compressing a fluid other than a synthesis gas compressor upstream of the heat exchanger.

 - the tank of the exhaustion column contains a reboiler

 - the tank of the separation column contains a reboiler

 means for sending the synthesis gas to the reboiler of the depletion column and, where appropriate, to the reboiler of the separation column upstream of the first phase separator.

 Possibly the apparatus does not include a turbine.

 The invention will be described in more detail with reference to the figures which show methods according to the invention.

In Figure 1, a partial condensation step is followed by a depletion step in a column. The synthesis gas containing hydrogen and carbon monoxide 1 as well as possibly methane and / or nitrogen and / or argon is purified in a purification unit 3 to remove water and / or methanol and / or carbon dioxide. The formed gas is partially cooled in a heat exchanger E and then serves to heat the liquid 23 of the bottom reboiler 21 of the depletion column 13; The thus cooled gas is further cooled to the cold end of the heat exchanger E by partially condensing and is sent to a phase separator 9 where separation of the formed liquid and gas takes place.

 A hydrogen-enriched gas 7 is withdrawn from the head of the phase separator and sent to a methanol production unit where carbon monoxide and hydrogen react by catalysis to form methanol or are sent for further purification in a methanol plant. PSA type unit. The hydrogen-depleted liquid 11 is expanded and sent to the top of the depletion column 13. The gas 15 formed at the top of the depletion column 13 heats up in the exchanger E. The liquid 17 is expanded in a valve and vaporizes in the heat exchanger E to form the product CO, without having been pressurized.

 The process is kept cold by an open cycle in which nitrogen gas 71 from an air separation apparatus and / or pipe is cooled in the heat exchanger E. Part 73 of the Nitrogen gas is optionally expanded to an intermediate temperature of the exchanger in a turbine 79 and returned thereto for heating. The remainder 75 of the nitrogen gas cools to the cold end of the heat exchanger, is expanded to a lower temperature in the valve 77 and then reheated in the heat exchanger E, mixed with the flow rate 73 The heated nitrogen 84 exits at the hot end of the heat exchanger and is sent to either a methanol wash unit.

 In the case where the synthesis gas contains methane, as illustrated in FIG. 2, the tank liquid 17 of the depletion column 13 of FIG. 1, containing methane and carbon monoxide, is sent to a column Part of the tank liquid 17A is sent directly to the middle of the separation column 37 after expansion in a valve and the remainder 17B is cooled in the heat exchanger E after expansion and sent to a level intermediate of column 37.

 A liquid rich in methane 42 is withdrawn from the tank of the column CO / CH4 37 and then is vaporized in the heat exchanger E. The carbon monoxide 41 exits as a gaseous product from the top of the column CO / CH4 37 and warms up in heat exchanger E.

The separation column 37 includes a head condenser 85 where the overhead gas of the column 37 is condensed and where a portion of the cycle nitrogen vaporizes. The process is held in cold by an open cycle in which nitrogen gas 71 from an air separation apparatus and / or pipe is cooled in the heat exchanger E. Part 73 of the nitrogen gas is expanded to an intermediate temperature of the exchanger in a turbine 79 and returned to it to heat up. The remainder of the nitrogen gas cools to the cold end of the heat exchanger, and is divided in half. A portion 76 is expanded to a lower temperature in the valve 80 and then sent to the enclosure 39 around the condenser 85. The other portion 78 is expanded in a valve 82. The nitrogen vaporizes in the enclosure to form a gas 83 which joins the expanded nitrogen in the valve 82 and the two flow rates are mixed to heat in the heat exchanger E and be mixed with the expanded nitrogen in the turbine 79. The heated nitrogen 84 exits at the end heat exchanger and is sent to a stripping column to either a methanol wash unit.

 A product of the distillation can be sent to the production of MEG (mono ethylene glycol), TDI / MDI (toluene diisocyanate and / or methylene diphenyl diisocyanate) or PC (Polycarbonates)

 An alternative of Figure 2 illustrated in Figure 3 illustrates the case where all the nitrogen cooled to the cold end of the exchanger E is sent by the valve 80 to the chamber 39 to be vaporized by the condenser 85. formed nitrogen 78 is heated in the exchanger and is mixed with the nitrogen 73 from the turbine 79 to form the product.

 For all the figures, a product of the distillation can be sent to the production of MEG (mono ethylene glycol), TDI / MDI (toluene di-isocyanate and / or methylene diphenyl di-isocyanate) or PC (Polycarbonates).

 In all figures, the exhaustion column operates at between 5 and 25 bar abs.

Claims

claims

Process for the cryogenic separation of a mixture of hydrogen and carbon monoxide and optionally methane and / or nitrogen and / or argon in which:

 i) The mixture is cooled in a heat exchanger (E) by introducing it to the hot end thereof, partially condensed and sent to a first phase separator (9) to produce a hydrogen-enriched gas (7) and a liquid (11) depleted in hydrogen, ii) the hydrogen depleted liquid is sent at least partly at the head of a depletion column (13), operating at a pressure between 5 and 25 bar abs, after expansion in a valve,

 iii) The hydrogen-enriched gas is reheated in the heat exchanger, optionally without having been expanded or separated and possibly not recycled to the synthesis gas

 iv) At least a portion of the bottom liquid (17, 17B) of the exhaust column vaporizes at least partially in the heat exchanger and optionally warms to the hot end of the heat exchanger to form a gas ,

 v) The overhead gas of the depletion column is reheated in the heat exchanger optionally without having been expanded or separated and possibly not recycled to the synthesis gas,

 vi) A carbon monoxide enriched product (15, 41) is derived from at least a portion of the bottom liquid of the depletion column and

 vii) A nitrogen-rich gas stream (71) is cooled in the heat exchanger by introducing it to the hot end thereof, leaving at least a portion of the cooled nitrogen-rich gas flow at the cold end thereof. at least a portion (73) is depressed, at least a portion of the nitrogen-rich gas flow is liquefied, the at least one liquefied portion (75, 76) is vaporized, the heat is heated, and the heating takes place at least partially in the heat exchanger before extracting at least a portion thereof as a nitrogen-rich gaseous product (84) and the nitrogen-rich gaseous product is fed to a stripping column as a stripping gas.

The process according to claim 1 wherein at least a portion (75) of the liquefied nitrogen rich gas is vaporized in the heat exchanger (E).

The method of claim 1 or 2 wherein a portion (73) of the cooled nitrogen gas is expanded in the heat exchanger (E) in a turbine (79).

Process according to one of the preceding claims wherein the nitrogen-rich gas (71) and the liquefied nitrogen-rich gas (75) are not separated by distillation.

5. Method according to one of the preceding claims wherein the mixture contains methane and is sent at least a portion (17A) of the vessel liquid (17) of the depletion column (13) to a separation column (37). ) to produce a carbon monoxide enriched gas (41) and a methane enriched liquid (42), and at least a portion of the liquefied nitrogen vaporizes in a head condenser (85) of the separation column.

The process according to claim 5 wherein all the nitrogen cooled to the cold end of the exchanger (E) is liquefied and then vaporizes in the overhead condenser (85).

7. The method as claimed in one of the preceding claims, in which the nitrogen-rich gaseous product (84) is sent to the bottom of a column fed at the top with a flow rate containing methanol and ammonia, in order to produce in the bottom of the column. purified methanol to ammonia.

8 Process according to one of the preceding claims wherein the mixture (1) is treated upstream of step i) by the methanol washing process.

Process according to one of the preceding claims, in which the mixture (1, 5) warms the tank of the exhaust column (13) and, if appropriate, the tank of the separation column (37) upstream of the first phase separator (9).

Apparatus for separating a mixture containing hydrogen, carbon monoxide and optionally methane and / or nitrogen and / or argon comprising a heat exchanger (E), a first phase separator (9), a depletion column (13), means for sending the synthesis gas to cool in the heat exchanger, means for sending the partially condensed synthesis gas to the first phase separator to produce an enriched gas hydrogen (7) and a hydrogen-depleted liquid (1), means for removing the hydrogen-enriched gas from the apparatus after reheating in the heat exchanger and without having relaxed, separated or recycled with the synthesis gas, means for sending the hydrogen-depleted liquid at least partly to the top of the depletion column after expansion in a valve, means for removing a head gas (15) from the exhaustion column of the apparatus after reheating in the heat exchanger and without having expanded or separated it, means for sending at least a portion (59, 69) of the bottoms liquid of the exhaust column vaporize at least partially in the heat exchanger and optionally heat up to the hot end of the heat exchanger to form a gas, means for deriving an enriched gas (41) in carbon monoxide from at least a portion of the bottom liquid (17) of the exhaustion column, means for sending nitrogen gas (71) to cool in the heat exchanger to the cold end, means for heating the cooled nitrogen gas to the end heat in the heat exchanger and means for sending the heated nitrogen (84) to a stripping column for use as a gas. stripping. Apparatus according to claim 10 comprising a stripping column, means for supplying the overhead stripping column with a mixture of methanol and ammonia and means for withdrawing ammonia-purified methanol from the column. An apparatus according to claim 10 or 11 wherein the nitrogen gas is not separated in the apparatus.

Apparatus according to claim 10, 11 or 12 comprising a separation column (37), means for sending at least a portion (Γ7Α) of the vessel liquid (17) from the depletion column (13) to the column of separation (37) for producing a carbon monoxide enriched gas (41) and a methane-enriched liquid (42) and means for sending at least a portion of the liquefied nitrogen to vaporize in a head condenser (85) of the separation column. Apparatus according to one of claims 10 to 13 not including a carbon monoxide refrigeration cycle.

Apparatus according to one of claims 10 to 14 comprising an expansion turbine (79) of nitrogen gas.