Method and apparatus for drying and purifying a fluid containing carbon dioxide and water
By optimizing heat exchange and energy recovery in CO2 capture and purification systems, the process addresses inefficiencies in pre-concentration and dryer size, enhancing efficiency and compactness of downstream units.
Patent Information
- Authority / Receiving Office
- FR · FR
- Patent Type
- Applications
- Current Assignee / Owner
- LAIR LIQUIDE SA POUR LETUDE & LEXPLOITATION DES PROCEDES GEORGES CLAUDE
- Filing Date
- 2024-12-05
- Publication Date
- 2026-06-12
AI Technical Summary
Existing CO2 capture and purification systems face inefficiencies due to the need for a pre-concentration step, which requires a large dryer and inefficient energy recovery when processing wet CO2 sources, leading to larger equipment and reduced efficiency in downstream separation units.
A process and device that recovers cooling capacity at the dryer outlet by transferring it to cooled water, using it to cool the incoming fluid, optimizing heat exchange and reducing dryer size through indirect or direct contact heat exchangers, and enhancing energy recovery by reheating the cooled water before expansion.
This approach allows for more efficient cooling and drying, reducing dryer size, increasing water flow rate, and improving energy recovery, making downstream separation units more efficient and compact.
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Abstract
Description
Title of the invention: Method and apparatus for drying and purifying a fluid containing carbon dioxide and water
[0001] The present invention relates to a method and apparatus for drying and purifying a fluid containing carbon dioxide and water.
[0002] CO2 capture and purification units using a relatively dilute source (10 to 50 mol% CO2), operating for example by partial condensation and / or distillation and / or solidification, require a CO2 pre-concentration step to make the main purification step more efficient (e.g., partial CO2 condensation). This pre-concentration step is most often carried out using a CO2 PSA or membranes. When the CO2 source is wet and intended for cryogenics, drying is required, typically installed before the pre-concentration step. The dryer is then relatively large because it processes the entire unconcentrated source. Pre-cooling with cold water allows for maximum water condensation and reduces the size of the dryer. The invention relates to the optimization of this cooling and drying step.
[0003] It is known from FR2884307 to relax the residue from the pre-concentration step to produce cold and to cool water by direct contact with the relaxed residue.
[0004] [Fig. 1] illustrates a prior art process in which a fluid at a first temperature Tl containing carbon dioxide and at least one impurity lighter than carbon dioxide chosen from the list: oxygen, nitrogen, argon, carbon monoxide, methane, helium and hydrogen, as well as water, is treated by the following steps: a. Cooling of the fluid from the first temperature T1 to a second temperature T2 in a heat exchanger E, b. drying of the partially dried fluid at the second temperature T2 by passing it through an adsorbent D in order to obtain a dried fluid, c. separation of the dried fluid by adsorption in a pretreatment unit P producing a fluid Fl depleted in carbon dioxide and a fluid F2 enriched in carbon dioxide.
[0005] The fluid Fl, called the residual fluid, is expanded in a turbine T and used to cool water in a tower by direct heat exchange. The expanded fluid is sent to the bottom of the tower W, which is fed at the top with water to be cooled. Carbon dioxide-depleted fluid V exits at the top of the tower W, and the cooled water exits at the bottom of the tower.
[0006] Problem solved by the invention
[0007] It is known to generate the cooled water by contacting water with the residue from the pre-concentration step after expansion. This residue is depleted in CO2 and enriched in another component of the fluid to be separated, for example nitrogen.
[0008] Another source of chillies could replace the relaxed residue.
[0009] The invention provides for pumping water cooled by the cooling source and using it to cool the fluid to be separated, which contains between 10 and 50 mol% CO2 and water. This heat exchange with the fluid to be separated can take place in a heat exchanger or directly in a cooling tower. The water used to cool the fluid heats up and may be expanded. Water present in the fluid to be separated condenses as a result of the cooling and is removed as condensate. The fluid still contains water and is sent to be dried in a dryer, for example, by temperature-switching adsorption.
[0010] The cooling capacity of the fluid to be separated is equal to the cooling capacity of the water by the cooling source, the latter being, for example, the residue from the pre-concentration stage. If the temperature of the fluid to be separated before cooling with water cooled by the cooling source is too high, the temperature after cooling with fresh water will not be as low as expected. In the case where the cooling source is the expanded residue, if the flow rate of the residue from the pre-concentration stage after expansion is relatively too low, the temperature after cooling with chilled water will not be as low as expected. This can occur when the fluid contains too little of the other component.
[0011] Then less water contained in the fluid to be separated will be condensed, leading to an enlargement of the following dryer.
[0012] Furthermore, since the cooling capacity is limited, the flow rate of cooled water will also be limited. This will result in significant heating of the water relative to the fluid to be separated. Thus, this exchange will be constrained on both the cold side (where maximum cooling is desired) and the hot side (since the flow rate is low, the cooled water will heat up to a temperature close to that of the wet source). Consequently, the size of the heat exchange medium between the fluid to be separated and the water cooled by the cooling source will be larger, implying a large exchange surface area for an indirect heat exchanger or a higher exchange area for a direct contact tower.
[0013] The fluid dried in the dryer may be intended for a pre-concentration step that is not necessarily optimized for relatively cold temperatures. This is particularly true for a pressure swing adsorption (PSA) unit. Thus, in the case of pre-drying, the pre-concentration step takes place at relatively low temperatures, and the downstream separation unit is therefore less efficient and / or larger.
[0014] Finally, similarly, if the pre-concentration step is carried out at a relatively low temperature, its residue will most often also be at a low temperature. Since it is most often expanded in a turbine (generating mechanical power) before being used for the generation of fresh water, its relatively low temperature results in lower energy recovery or requires additional heat consumption before expansion to compensate for this effect. According to one aspect of the invention, a process is provided for drying and purifying a fluid at a first temperature Tl containing between 10 and 50 mol% carbon dioxide, as well as at least one impurity lighter than carbon dioxide selected from the following list: oxygen, nitrogen, argon, carbon monoxide, methane, helium, and hydrogen, as well as water, comprising the following steps: a. Cooling of the fluid at the first temperature Tl to a second temperature T2 against water at a third temperature T3 lower than the first temperature Tl and partial condensation of the water contained in the fluid, the cooling water heating up to a fourth temperature T4, b. separation of the condensed water to obtain a partially dried fluid at the second temperature T2, c. drying of the partially dried fluid at the second temperature T2 by passing through an adsorbent in order to obtain a fluid dried at a fifth temperature T5, d. heating the dried fluid to the fifth temperature T5 against water which is cooling in order to obtain water at a sixth temperature T6 and a dried fluid at a seventh temperature T7, e. cooling the water to the sixth temperature T6 by heat exchange with a cooling source at an eighth temperature T8, which is colder than the sixth temperature T6, generating water preferably at the third temperature T3, and f. use of the water generated, preferably at the third temperature T3, during step e) to cool the fluid to the first temperature Tl during step a).
[0015] According to other optional aspects: • The fluid dried at the seventh temperature T7 is separated into a first fraction at a ninth temperature T9, which is more concentrated in CO2 than the fluid dried at the seventh temperature T7, and a second fraction at a tenth temperature T10, which is less concentrated in CO2 than the fluid dried at the seventh temperature T7. • the second fraction at the tenth temperature T10 is expanded, optionally after heating, generating a second fraction at the eighth temperature T8 used as the source of cooling for step e), • The cooling of step e) is achieved by direct contact heat exchange between the water at the sixth temperature T6 and the cooling source, • The cooling of step e) is achieved by indirect contact heat exchange between the water at the sixth temperature T6 and the cooling source, • The cooling of step a) is achieved by direct contact heat exchange between the fluid at the first temperature T1 and the water at the third temperature T3, • the cooling of stage a) is achieved by indirect contact heat exchange between the fluid at the first temperature T1 and the water at the third temperature T3, for example in a shell and tube heat exchanger, • The separation of the fluid dried at the seventh temperature T7 is carried out by a pressure-switching adsorption system. • The separation of the fluid dried at the seventh temperature T7 is carried out by a membrane system, • the first fraction at the ninth temperature T9 more concentrated in CO2 is obtained from the fluid dried at a seventh temperature T7, which is then compressed and purified by partial condensation and / or distillation and / or solidification in order to produce a third fraction more concentrated in CO2 than the first fraction. • the water that cools in step d) includes at least some of the water that heats up in step a), • the water that cools in step d) does not include any part of the water that heats up in step a).
[0016] According to another object of the invention, a device is provided for drying and purifying a fluid at a first temperature Tl containing between 10 and 50 mol% carbon dioxide as well as at least one impurity lighter than carbon dioxide chosen from the list: oxygen, nitrogen, argon, carbon monoxide, methane, helium and hydrogen as well as water comprising: • means of cooling the fluid to the first temperature Tl up to a second temperature T2 against water at a third temperature T3 lower than the first temperature Tl allowing partial condensation of the water contained in the fluid, the cooling water heating up to a fourth temperature T4, • means of separating the condensed water in order to obtain a partially dried fluid at the second temperature T2, • a dryer for drying partially dried fluid at a second temperature T2 per pass, comprising an adsorbent and means for sending the partially dried fluid to circulate through the adsorbent in order to obtain a fluid dried at a fifth temperature T5, • means of heating the dried fluid to the fifth temperature T5 against cooling water in order to obtain water at a sixth temperature T6 and a dried fluid at a seventh temperature T7, • means of cooling water to the sixth temperature T6 by heat exchange with a cooling source at an eighth temperature T8, colder than the sixth temperature T6, generating water preferably at the third temperature T3, and • means for sending the generated water, preferably at the third temperature T3, into the water cooling means at the sixth temperature to cool the fluid to the first temperature Tl in the fluid cooling means as cooling water.
[0017] According to other optional aspects, the device comprises: • a first separation apparatus to separate the fluid dried at the seventh temperature T7 into a first fraction at a ninth temperature T9 more concentrated in CO2 than the fluid dried at the seventh temperature T7 and a second fraction at a tenth temperature T10 less concentrated in CO2 than the fluid dried at the seventh temperature T7, • an expansion turbine and means for sending at least part of the second fraction to the expansion turbine, • Water cooling methods are means of heat exchange with direct contact between the water at the sixth temperature T6 and the source of cooling, • Water cooling methods are indirect contact heat exchange methods between water at the sixth temperature T6 and the cooling source, • The means of cooling the fluid to be dried are means of direct or indirect heat exchange, for example in a shell and tube heat exchanger, • The separation device is a pressure-switching adsorption system, • The separation device is a membrane system, • a second partial condensation separation device and / or distillation and / or solidification linked to the first separation apparatus to separate the first fraction in order to produce a third fraction more concentrated in CO2 than the first fraction.
[0018] means for sending water which cools against the fluid dried in the dryer includes at least a part of the water which heats up against the fluid to be dried.
[0019] The invention consists of recovering the cooling capacity at the dryer outlet by transferring it to the cooled water before it is cooled by the cooling capacity source, which may be, for example, the residue from the pre-concentration stage. To do this, the cooled water exchanges heat in an indirect contact heat exchanger (for example, a plate and fin heat exchanger or a shell and tube heat exchanger) with the fluid to be separated, which has been dried at the dryer outlet.
[0020] This configuration makes it possible to utilize the cooling energy that was previously mainly lost to the cooling source, for example, the residual heat from the pre-concentration stage during its reheating before expansion. Thus, the flow rate of circulating cooled water can be increased for the same cold temperature obtained after cooling by the cooling source, or for the same flow rate, a colder temperature can be achieved.
[0021] This allows the wet source to be cooled even more and therefore the size of the dryer to be reduced.
[0022] In particular, if a cooling tower with direct contact between the water and the wet source is used, the increase in the flow rate of fresh water makes it possible to reach temperatures at the inlet of the dryer with less constraint in terms of approach, allowing the invention to be taken to the maximum.
[0023] The higher water flow rate also helps to limit the water temperature after it has been heated relative to the cooling fluid to be separated. The contact area between the fluid to be separated and the water cooled by the cold source after the exchange is thus increased. This allows for a more compact heat exchanger, and may even alleviate constraints that some technologies could not tolerate. Too small a contact area makes the industrial use of a shell-and-tube heat exchanger impossible. Thus, the heat exchange surface area of an indirect contact heat exchanger or the height of a direct contact cooling tower is reduced.
[0024] Finally, the temperature at the inlet of the pre-concentration stage, when present, is then increased, which can make it more efficient, particularly in the case of a pressure swing adsorption (PSA) unit. The remaining CO2-depleted PSA is also available at a higher temperature, minimizing its heat demand before expansion.
[0025] The invention will be described in more detail with reference to the figures where:
[0026] [Fig.2] represents a method according to the invention,
[0027] [Fig.3] represents a method according to the invention.
[0028] [Fig. 2] represents a process for drying and purifying a fluid F at a first temperature Tl containing between 10 and 50 mol% carbon dioxide as well as at least one impurity lighter than carbon dioxide chosen from the list: oxygen, nitrogen, argon, carbon monoxide, methane, helium and hydrogen, as well as water. This fluid F can, for example, come from a cement plant, a lime production plant, or a steel production plant.
[0029] Fluid F is in a gaseous state and is cooled from a first temperature T1 to a second temperature T2 against water at a third temperature T3, lower than the first temperature T1, in a heat and mass exchange tower by direct contact C with water 1 supplied to the top of the tower, with fluid F arriving at the bottom of the tower. Water contained in fluid F is cooled by contact with water 1 to a temperature T2 lower than the first temperature T1, and consequently, water contained in fluid F condenses. The water 3 that exits the tower in a tank at a fourth temperature T4 includes condensed water contained in fluid F.
[0030] The partially dried fluid Fd exiting at the top of tower C at the second temperature T2, lower than the first temperature T1, still contains water and is dried in a dryer D by temperature-toggle adsorption to produce a dry fluid Fdd at a fifth temperature T5.
[0031] The dry fluid Fdd at the fifth temperature T5 is heated in an indirect contact heat exchanger R against water, for example at least part of the water flow 3 in order to obtain water 5 at a sixth temperature T6 and a dried fluid Fddd at a seventh temperature T7 higher than the fifth temperature T5.
[0032] The water 5 cooled in the heat exchanger R is again cooled by a source of cooling and returned to the top of the tower C. Here the cooling takes place in a tower W with direct contact: the source of cooling is a gas Fl expanded in a turbine T which cools the water 5 coming from the exchanger R in the direct heat exchange cooling tower W producing a heated gas V at the top of the tower W and the cooled water 1 at the bottom of the tower W.
[0033] The dry fluid Fddd at the seventh temperature T7 is separated in a unit P by pressure-toggle adsorption and produces at least one gas F2 enriched in CO2 and depleted in at least one other component and a gas Fl enriched in at least one other component and depleted in CO2. The gas Fl is expanded in the turbine T, optionally after being heated.
[0034] The gas F2 is compressed, cooled and separated by partial condensation and / or distillation and / or solidification in the separation unit CC forming a product F3 enriched in CO2
[0035] [Table 1] Temperature Current Typical Range (°C) T1 Fluid F [10-60] T2 Fluid Fd [5-15] T3 Water 1 [1 - 10] T4 Water 3 [10-60] T5 Fluid Fdd [10-20] T6 Water 5 [10-40] T7 Fluid Fddd [20 - 60] T8 Cooling Source [-10-10]
[0036] Unlike [Fig. 2], [Fig. 3] does not include a tower C. The fluid F is cooled by a cooler K through indirect heat exchange with water 1 from tower W. The fluid F is cooled there to condense the water it contains, and the condensed water H is removed from a separator S, which also produces the dried fluid Fd. The partially dried fluid Fd is dried in a dryer D. The water 1 that has cooled the cooler K is sent, at least in part, as flow 3 to the heat exchanger R to reheat the dried fluid Fdd downstream of the dryer D, and the cooled water 5 is returned to tower W to be cooled again to the temperature of the water 1.
[0037] As in [Fig. 2], the dry fluid Fddd at the seventh temperature T7 is separated in a unit P by pressure-toggle adsorption and produces at least one gas F2 enriched in CO2 and depleted in at least one other component and one gas Fl enriched in at least one other component and depleted in CO2. The gas Fl is expanded in the turbine T, optionally after being heated.
[0038] The gas F2 is compressed, cooled and separated by partial condensation and / or distillation and / or solidification in the separation unit CC (not shown, see [Fig.2]) forming a product F3 enriched in CO2.
[0039] For both figures [Fig.2] and [Fig.3], unit P can be a membrane separation unit.
[0040] For both figures [Fig.2] and [Fig.3], a portion BD of the cooled water from tower C or cooler K can be removed from circulation to avoid the accumulation of elements contained in the fluid F, for example solid impurities, such as dust.
[0041] For both figures [Fig.2] and [Fig.3], water M can be added to the cycle to compensate for water losses, for example leaving the device in the gas V.
Claims
Demands
1. A process for drying and purifying a fluid (F) at a first temperature Tl containing between 10 and 50 mol% carbon dioxide and at least one impurity lighter than carbon dioxide selected from the list: oxygen, nitrogen, argon, carbon monoxide, methane, helium and hydrogen, as well as water, comprising the following steps: a. Cooling (C) of the fluid at the first temperature T1 to a second temperature T2 against water (1) at a third temperature T3 lower than the first temperature T1 and partial condensation of the water contained in the fluid, the cooling water heating up to a fourth temperature T4 b. separation of the condensed water (3,BD,H) to obtain a partially dried fluid (Fd) at the second temperature T2 c. drying of the partially dried fluid at the second temperature T2 by passing through an adsorbent (D) in order to obtain a dried fluid (Fdd) at a fifth temperature T5 d. heating (R) of the dried fluid at the fifth temperature T5 against water which cools in order to obtain water (5) at a sixth temperature T6 and a dried fluid (Fddd) at a seventh temperature T7 e. cooling (W,K) of the water to the sixth temperature T6 by heat exchange with a source of cooling (Fl) at an eighth temperature T8 colder than the sixth temperature T6 generating water (1) preferably at the third temperature T3 and f. use of the water generated, preferably at the third temperature T3, during step e) to cool the fluid to the first temperature Tl during step a).
2. A process according to the preceding claim, wherein the fluid dried at the seventh temperature T7 (Fddd) is separated (P) into a first fraction (F2) at a ninth temperature T9 more concentrated in CO2 than the fluid dried at the seventh temperature T7 and a second fraction (Fl) at a tenth temperature T10 less concentrated in CO2 than the fluid dried at the seventh temperature T7
3. A process according to claim 2 wherein the second fraction (Fl) at the tenth temperature T10 is relaxed (T), optionally after heating, generating a second fraction at the eighth temperature T8 used as a source of frigories for step e).
4. A method according to any one of the preceding claims wherein the cooling of step e) is obtained by direct contact heat exchange (W) between the water at the sixth temperature T6 and the source of cooling (Fl).
5. A method according to any one of claims 1 to 3 wherein the cooling of step e) is obtained by indirect contact heat exchange between the water at the sixth temperature T6 and the source of cooling (Fl).
6. A method according to any one of the preceding claims wherein the cooling (C) of step a) is obtained by direct contact heat exchange between the fluid (F) at the first temperature T1 and the water (1) at the third temperature T3.
7. A method according to any one of claims 1 to 5 wherein the cooling of step a) is obtained by indirect contact heat exchange (K) between the fluid (F) at the first temperature T1 and the water (1) at the third temperature T3, for example in a shell and tube heat exchanger.
8. A method according to any one of claims 2 or 3 to 7 when dependent on claim 2, wherein the separation (P) of the fluid dried at the seventh temperature T7 (Fddd) is carried out by a pressure-toggle adsorption system
9. A method according to any one of claims 2 or 3 to 7 when dependent on claim 2, wherein the separation (P) of the fluid dried at the seventh temperature T7 (Fddd) is carried out by a membrane system
10. A process according to claims 8 or 9 wherein the first fraction (F2) at the ninth temperature T9, more concentrated in CO2 than the fluid dried at a seventh temperature T7 (Fddd), is compressed and then purified by partial condensation and / or distillation and / or solidification (CC) to produce a third fraction (F3) more concentrated in CO2 than the first fraction.
11. 11 A method according to any one of the preceding claims wherein the water (3) which cools in step d) comprises at least a portion of the water which heats up in step a).