FR3100057A1 - PROCESS AND APPARATUS FOR THE PRODUCTION OF CARBON MONOXIDE BY PARTIAL CONDENSATION - Google Patents

Abstract

Title: PROCESS AND APPARATUS FOR THE PRODUCTION OF CARBON MONOXIDE BY PARTIAL CONDENSATION In a process for the separation by cryogenic distillation of a mixture of hydrogen, methane and carbon monoxide (1), the mixture is cooled in a first heat exchanger. heat (3,9) and it is partially condensed in at least a second heat exchanger (11,13) which is a bottom reboiler of a first or second column (K1, K2) of the column system and is sent to an intermediate level of the first column at least a part (17,23) of the liquid produced by the partial condensation. Abstract figure: Fig. 1

Description

METHOD AND APPARATUS FOR PRODUCTION OF CARBON MONOXIDE BY PARTIAL CONDENSATION

The present invention relates to a process and an apparatus for producing carbon monoxide by partial condensation.

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

Generation of synthesis gas (mixture containing H ₂ , CO, CH ₄ , CO ₂ , Ar and N ₂ mainly). Among the various industrial routes for the production of syngas, that based on coal gasification seems to be developing more and more, particularly in countries rich in coal deposits such as China. The process of partial oxidation of natural gas can also prove interesting for the production of CO alone or with low H2/CO production ratios. Another route is steam reforming.

Syngas purification . We find :

• a washing unit with a liquid solvent to remove most of the acid gases contained in the synthesis gas.
• an adsorbent bed purification unit.
• a cryogenic separation unit called a cold box for the production of CO.

In the case where the synthesis gas is produced from an entrained bed or fluidized bed coal gasification, the cold box process is partial condensation. For MEG, TDI/MDI or PC applications, for example, it is necessary to include a CH4 separation column in the cold box.

In the diagram of EP 0677483, the reboiling energies of the two fast separation (“flash”) and CO/CH4 separation columns are provided by cooling the synthesis gas in the main exchanger and by the cycle. The synthesis gas is cooled as a whole to the cold end of the heat exchanger before entering the hydrogen separation separator pot.

The disadvantages are that:

• The reboiling of the two columns in the exchange line does not allow good regulation of the reboiling energies.
• The energy consumption of the refrigeration cycle is high because the syngas is cooled in its entirety to the cold end. There is no intermediate syngas condensation pot to extract the condensed liquid and avoid undercooling it.

WO18039313 describes reboilers independent of the two columns with syngas cooling but all of the syngas (liquid and reboiler outlet gas) is cooled to the cold end of the exchange line according to Figures 3, 4 and 5. In figures 1 and 2, the two reboilers are in series, the entire output of the flash column reboiler is sent to the common separator pot with the cold end. The CO/CH4 column reboiler outlet liquid is subcooled in the exchange line.

The disadvantages are that:

• If the two reboilers are in series, this creates instabilities in the reboiling energy of the stripping column when the temperature of the outlet of the first reboiler varies according to the disturbances in the composition of the incoming syngas.
• The output of the second reboiler is sent directly to the high pressure syngas pot. In order for the outlet of the second reboiler to be at a temperature close to the pot of high pressure syngas, the pressure of the stripping column must be lowered, which has the effect of increasing the quantity of CO in the overhead gas. . The CO efficiency is thus reduced if the flash gas is not recycled, or the compression energy of the overhead gas recycling is increased.
• The CO/CH4 column is operated at low pressure following the drop in pressure of the stripping column, which increases the compression energy of the CO output from this column.
• The energy of the refrigeration cycle is high because all the synthesis gas is cooled to the cold end, the liquid at the outlet of the partial condensation pot of the synthesis gas at the outlet of the reboilers is subcooled and therefore consumes the cycle refrigerated.

In US6266976, the reboiling energies of the two columns are provided by cooling the synthesis gas and the cycle in the exchange line. The liquid from the first partial condensation pot (106) of the synthesis gas leaving the first exchanger of the exchange line is sent to the stripping column but as reflux and not at an intermediate level (fluid 146).

Part of the liquid from the second synthesis gas partial condensation pot (112) is sent as reflux from the stripping column but after having been reheated in the exchange line.

The disadvantages are:

• The reboiling of the two columns in the exchange line does not allow good control of the reboiling energies.
• High CO content in the flash gas leaving the top of the exhaustion column which leads to an increase in the recycling energy of the fast separation gas (in English “flash”) or else loss of CO yield if the fast separation gas (in English "flash") is not recycled.

According to one object of the invention, there is provided a process for the separation by cryogenic distillation in a system of columns of a mixture of hydrogen, methane and carbon monoxide in which:

1. The mixture is cooled in a first heat exchanger and it is partially condensed in at least a second heat exchanger which is a bottom reboiler of a first or second column of the column system and it is sent to an intermediate level of the first column at least part of the liquid produced by the partial condensation or a liquid derived from this liquid by at least one partial condensation stage, only the mixture and the bottom liquid of the column exchanging heat in the second heat exchanger, the vaporized bottom liquid being returned to the column from which it originated.
2. Hydrogen-enriched overhead gas is withdrawn from the first column and reheated in the first heat exchanger.
3. A liquid enriched in carbon monoxide and methane is withdrawn from the bottom of the first column and sent to at least one intermediate level of the second column.
4. A liquid rich in methane is withdrawn from the bottom of the second column and a fluid rich in carbon monoxide from the head of the second column, and
5. Refrigeration is produced to keep the process cold by means of a refrigeration cycle.

According to other optional aspects:

• at least part of the cooled mixture is sent to the second heat exchanger which is a reboiler of the first column.
• at least part of the cooled mixture is sent to the second heat exchanger which is a reboiler of the second column.
• at least part of the cooled mixture is sent to be cooled to the second exchanger which is a reboiler of the second column and then the cooled mixture is sent to a third exchanger which is a reboiler of the first column.
• at least part of the cooled mixture is sent to partially condense in the second exchanger which is a reboiler of the second column to produce a gas and a liquid, then the gas is sent to a third exchanger which is a reboiler of the first column and at least part of the liquid produced by at least partial condensation of the gas is sent in the third exchanger to the intermediate point of the first column.

• a condensed part, produced following at least one stage of partial condensation of the mixture, is sent to the top of the first column of the system of columns.
• the first column has a bottom reboiler and no overhead condenser.
• the first column operates at between 13 and 16 bars abs.
• the second column operates at a pressure above 6 bars abs.
• the second column has a bottom reboiler and an overhead condenser.
• the overhead gas from the first column contains less than 35 mol%, or even less than 25 mol%, of carbon monoxide.
• the top gas from the first column contains more than 60% mol, or even more than 75% mol, of hydrogen.
• the mixture cools in the first heat exchanger to an intermediate temperature thereof and then leaves the first heat exchanger before being sent to the reboiler.
• the carbon monoxide-rich fluid from the top of the second column and/or the hydrogen-enriched overhead gas from the first column is cooled in the first heat exchanger from the cold end of the first heat exchanger.
• a derivative gas is cooled in the coldest part of the first heat exchanger by partial condensation of the mixture cooled in the first heat exchanger.

According to another object of the invention, there is provided an apparatus for the separation by cryogenic distillation of a mixture of hydrogen, methane and carbon monoxide comprising a system of columns comprising a first column and a second column, a first heat exchanger, a second heat exchanger, means for sending the mixture to cool in the first heat exchanger, means for sending the cooled mixture to partially condense in at least the second heat exchanger which is a the first or the second column of the system of columns, means for sending to an intermediate level of the first column at least part of the liquid produced by the partial condensation or a liquid derived from this liquid by at least one partial condensation step , only the mixture and bottom liquid from the column exchanging heat in the second heat exchanger, means for returning the vaporized bottom liquid to the column from which it comes, means for drawing off a hydrogen-enriched overhead gas of the first column, means for sending the overhead gas to heat up in the first heat exchanger, means for withdrawing a liquid enriched in carbon monoxide and methane from the bottom of the first column, means for sending the liquid enriched in carbon monoxide and in methane at at least an intermediate level of the second column, means for withdrawing a liquid rich in methane from the bottom of the second column, means for withdrawing a fluid rich in carbon monoxide from the head of the second column and a refrigeration cycle to produce refrigeration to keep the process cold.

The invention will be described in great detail with reference to Figures 1 to 3 which illustrate methods according to the invention.

describes a process for separating a gas mixture, such as a synthesis gas, according to the invention. The two reboilers in parallel with a common pot at the outlet of the two reboilers, the resulting gas is cooled in the exchange line and the liquid fraction is sent to the intermediate part of the stripping column.

A gas mixture 1 containing at least carbon monoxide, hydrogen and methane is cooled in the first section 3 of a two-section heat exchanger 3.9.

The cooled mixture is divided into two parts 5.7. Part 7 is partially condensed by cooling it in a bottom reboiler 13 of a K1 column, which is a stripping column. Part 5 is partially condensed by cooling it in a bottom reboiler of a K2 column which is a CO/CH4 distillation column. The partially condensed flows are mixed in a phase separator 15.

The gas produced is cooled in section 9 of the exchanger where it partially condenses and is sent to a phase separator S2. Gas 63 from phase separator S2 is reheated in sections 9.3. The liquid from phase separator S2 is sent to the head of column K1.

The liquid 17 from the phase separator 15 is expanded and then mixed with another flow to form a two-phase flow 19. The flow 19 is separated in a phase separator to form a gas 22 and a liquid 23, the two being sent to a level intermediate column K1.

Part 45 of the liquid from phase separator 15 is cooled in section 9 of the heat exchanger where it partially condenses before being sent to a phase separator S1.

The bottom liquid of the phase separator S2 is divided into two. Part 61 is sent as liquid to the top of column K1. The remainder 43 is relaxed and supplies the phase separator S1. The liquid 41 formed in the separator S1 vaporizes in the section 9 to form a mixed gas with the gas from the separator 1 and the flow formed 45 is mixed with the flow 17 from the separator 15.

The overhead gas from column K1 heats up in the two sections 9.3 to form a gas 39 rich in hydrogen.

Bottom liquid from column K1 is vaporized in reboiler 13 and returned to column K1.

Column K1 operates at a pressure between 13 and 16 bar abs and overhead gas 21 has the following composition:

• CO: 20-35% mol
• H2: 65-80%
• CH4: 0.1%
• N2: 0.5%
• Ar: 0.1%

Bottom liquid from column K1 is divided in two to form two expanded liquid flows 27,29,31. The expanded flow 31 is sent to an intermediate level of the second column K2 and the expanded flow 27 partially heats up in section 9 to be sent to an intermediate level of the second column K2 lower than that of the arrival of the flow 31.

Bottom liquid 21 is sent to reboiler 11, vaporizes and is returned to column K2, which operates at a pressure greater than 6 bar absolute.

Another bottom liquid 23 from column K2 is reheated in section 3 to form a methane-rich product.

An overhead gas 37 from column K2 is reheated in sections 9.3 to form a product rich in carbon monoxide.

The top condenser C of the CO/CH4 column K2 is supplied with liquid by a nitrogen cycle, comprising two compressors V1, V2 and with two levels of vaporization at different pressures in section 9. This cycle is completely independent of the rest of the process and can be replaced by a different refrigeration cycle.

describes a process for separating a gas mixture according to the invention, similar to that of FIG. 1. The two reboilers 11,13 are in series. Thus the mixture 1 cooled in section 3 only arrives as flow 5 in the first reboiler 11, vaporizes the bottom liquid 21 and is thereby cooled. The cooled mixture is sent to the second reboiler 13 where it partially condenses. A separator pot 65 is located at the outlet of the second reboiler 13. The vapor fraction 77 from the second pot is cooled in the exchange line and separated in the separator S2 to form a liquid feed for the column K1 while the liquid fractions and gases 67 derived by partial condensation of liquid 67 from pot 65 are sent to the intermediate part of column K1.

This makes it possible to reduce the loss of CO at the top of the column and to reduce the energy of the cycle compressor because the liquid fraction leaving the reboiler is not undercooled.

Thus the overhead gas flow contains less than 30% carbon monoxide, or even less than 25 mol% carbon monoxide.

describes a process for separating a gas mixture according to the invention, similar to that of FIG. 1. The two reboilers 11,13 are in series. Thus the mixture 1 cooled in section 3 only arrives as flow 5 in the first reboiler 11, vaporizes the bottom liquid 21 and is partially condensed. The partially condensed mixture is sent to the separator pot 15 which is located at the outlet of the first reboiler 11. The liquid 17 from the pot 15 is sent to a pot 65 whose liquid 67 is sent to an intermediate part of the column K1. The gas 77 from the pot 15 is partially condensed in the second reboiler 13. A second pot 65 is located at the outlet of the second reboiler 13. The vapor fraction 77 from the second pot 65 is cooled in the exchange line 9 while the fractions Liquid 17.67 from the two reboiler outlet pots 15.65.75 respectively are sent to the intermediate part of the K1 column.

The solution is to be selected from those of the three figures depending on the pressure of the incoming syngas 1 and the CO content in the incoming syngas 1.

Claims (10)

Process for the separation by cryogenic distillation in a column system of a mixture of hydrogen, methane and carbon monoxide (1,5,7) in which:

1. The mixture is cooled in a first heat exchanger (3.9) and partially condensed in at least a second heat exchanger (11.13) which is a bottom reboiler of a first or second column (K1, K2 ) of the column system and at least part of the liquid (17.67) produced by the partial condensation or a liquid (23.75) derived from this liquid (67) is sent to an intermediate level of the first column (K1) by at least one partial condensation step, only the mixture and bottom liquid (21) of the column exchanging heat in the second heat exchanger, the vaporized bottom liquid being returned to the column from which it originated.
2. A hydrogen-enriched overhead gas (39) is withdrawn from the first column and heated in the first heat exchanger,
3. A liquid (25,27,29) enriched in carbon monoxide and methane is drawn off from the bottom of the first column (K1) and sent to at least one intermediate level of the second column (K2).
4. A liquid (23) rich in methane is withdrawn from the bottom of the second column and a fluid rich in carbon monoxide (37) from the head of the second column, and
5. Refrigeration is produced to keep the process cold by means of a refrigeration cycle (V1,V2,35,46,47,49,53).

Process according to Claim 1, in which at least part (7) of the cooled mixture is sent to the second heat exchanger (13) which is a reboiler of the first column (K1). Process according to Claim 1 or 2, in which at least part (5) of the cooled mixture is sent to the second heat exchanger which is a reboiler (11) of the second column (K2). Process according to claim 3, in which at least part of the cooled mixture is sent to be cooled to the second exchanger (11) which is a reboiler of the second column (K2) and then the cooled mixture is sent to a third exchanger which is a reboiler (13) of the first column (K1). Process according to claim 3, in which at least part of the cooled mixture is sent to partially condense in the second exchanger (11) which is a reboiler of the second column (K2) to produce a gas (77) and a liquid (17) , then the gas is sent to a third exchanger (13) which is a reboiler of the first column (K1) and at least part of the liquid produced by at least partial condensation of the gas is sent in the third exchanger to the intermediate point of the first column. Process according to one of the preceding claims, in which a condensed part (61), produced following at least one stage of partial condensation of the mixture, is sent to the top of the first column (K1) of the system of columns. Process according to one of the preceding claims, in which the first column (K1) has a bottom reboiler (13) and has no overhead condenser. Method according to one of the preceding claims, in which the mixture (1) is cooled in the first heat exchanger (3,9) to an intermediate temperature thereof and then leaves the first heat exchanger before being sent to the reboiler. Process according to one of the preceding claims, in which the fluid (37) rich in carbon monoxide from the top of the second column (K2) and/or the top gas (39) enriched in hydrogen from the first column (K1) cools (ssen) t in the first heat exchanger (3,9) from the cold end of the first heat exchanger. Apparatus for the separation by cryogenic distillation of a mixture of hydrogen, methane and carbon monoxide (1,5,7) comprising a column system comprising a first column (K1) and a second column (K2), a first heat exchanger (3,9), a second heat exchanger (11,13), means for sending the mixture to cool in the first heat exchanger, means for sending the cooled mixture to partially condense in at least the second heat exchanger which is a bottom reboiler of the first or second column of the column system, means for sending to an intermediate level of the first column at least a part (75) of the liquid produced by the partial condensation or a liquid derived from this liquid by at least one partial condensation step, only the mixture and bottom liquid of the column exchanging heat in the second heat exchanger, means for returning the vaporized bottom liquid to the column from which it comes, means for withdrawing an overhead gas (39) enriched in hydrogen from the first column, means for sending the overhead gas to heat up in the first heat exchanger, means for withdrawing a liquid enriched in carbon monoxide and in methane (25, 29) from the tank of the first column, means for sending the liquid enriched in carbon monoxide and in methane to at least one intermediate level of the second column, means for withdrawing a liquid rich in methane from the tank (23) of the second column, means for withdrawing a fluid rich in carbon monoxide (37) from the top of the second column and a refrigeration cycle (V1, V2, C, 35, 46,47,49 to produce refrigeration to keep the process cold.