FR2777477A1 - Purification of a gas flow containing carbon dioxide, water vapor and/or hydrocarbons - Google Patents

Abstract

At least one impurity is adsorbed in an adsorption bed, at an adsorption temperature (Tads) and pressure (Pads), and at least part of the adsorption bed is regenerated at a regeneration temperature (Treg) and pressure (Preg). The temperatures and pressures are chosen so: 7.3 less than (Treg/Tads) x (Pads/Preg) less than 33 - DETAILED DESCRIPTION - Preferably, 10 less than (Treg/Tads) x (Pads/Preg) less than 25. The adsorption is carried out at an adsorption flow rate (Dads) and the regeneration at a regeneration flow rate (Dreg), such that: 2.8 less than (Treg/Tads) x (Pads/Preg) x (Dreg/Dads) less than 14. Preferably, 3 less than (Treg/Tads) x (Pads/Preg) x (Dreg/Dads) less than 12. The adsorbent is chosen from impregnated, calcined activated aluminas, and exchanged or non-exchanged zeolites, preferably from among the X zeolites with a Si/Al ratio below 1.15 or LSX zeolites with a Si/Al ratio around 1.The adsorption pressure is between 3 x 105 Pa and 6 x 106 Pa and/or the regeneration pressure is between 105 Pa and 3 x 105 Pa. The adsorption temperature is between 0 deg. C and 80 deg. C and/or the regeneration temperature is between 20 deg. C ad 200 deg. C. The ratio of adsorption flow to regeneration flow is between 5% and 80%.The process is a VSA or TSA process

Description

 The object of the present invention is to provide a process for pretreatment or purification of gas flow, in particular atmospheric air, before cryogenic separation of said air by cryogenic distillation.

 It is known that atmospheric air contains compounds to be removed before the introduction of said air into the heat exchangers of the cold box of an air separation unit, in particular the carbon dioxide (CO2), steam vapor and water (H2O) and / or hydrocarbons for example.

 Indeed, in the absence of such pretreatment of the air to remove its impurities CO2 and water, there is a condensation and an ice solidification of these impurities during the cooling of the air at cryogenic temperature, from which problems of clogging of the equipment may arise, in particular heat exchangers, distillation columns, etc.

 In addition, it is also customary to remove hydrocarbon impurities that may be present in the air in order to prevent their too high concentration in the bottom of the distillation column or columns, and thus to overcome any risk of 'explosion.

Currently, this pre-treatment of the air is carried out, as the case may be, by TSA (Temperature
Swing Adsorption) or PSA (Pressure Swing)
Adsorption); by PSA process is meant the PSA processes proper, VSA processes (Vacuum Swing
Adsorption), VPSA methods and the like.

Conventionally, a TSA process cycle of air purification comprises the following steps:
a) purification of the air by adsorption of the impurities at superatmospheric pressure and at room temperature,
b) depressurization of the adsorber to atmospheric pressure or below atmospheric pressure,
c) regeneration of the adsorbent at atmospheric pressure, in particular by waste gases or waste gases, typically impure nitrogen from an air separation unit and reheated to a temperature usually between 100 and 200 ° C. by means of one or more heat exchangers,
d) cooling at ambient or subambient temperature of the adsorbent, particularly by continuing to introduce said waste gas from the air separation unit, but not reheated,
e) repressurization of the adsorber with purified air from, for example, another adsorber in the production phase.

 Usually, a PSA process cycle of air purification comprises, for its part, substantially the same steps a), b) and e), but differs from a TSA process by a lack of heating of the waste gas or gases during of the regeneration step (step c)), so the absence of step d) and, in general, a shorter cycle time than TSA process.

 Generally, the air pretreatment devices comprise two adsorbers, operating alternately, that is to say that one of the adsorbers is in the production phase, while the other is in the regeneration phase.

 Such TSA air purification processes are described in particular in US-A-3738084 and FR-A-7725845.

 In general, the removal of CO2 and water vapor is carried out on one or more beds of adsorbents, preferably several beds of adsorbents, namely generally a first adsorbent intended to preferentially stop water, for example a bed of activated alumina, silica gel or zeolites, and a second adsorbent bed to preferentially stop the Cc2, for example a zeolite. Mention may especially be made of US-A-5531808, US-A-5587003 and US-A-4233038.

 Achieving effective removal of CO2 and water vapor in the air on the same single bed of adsorbent is not easy, because the water has an affinity for adsorbents significantly higher than that of CO2 . In other words, the selectivity of adsorbents is more favorable to water than CO2.

 In addition, in order to regenerate a saturated adsorbent in water, it is customary to bring this adsorbent to a regeneration temperature greater than 1000C.

 However, very few adsorbents currently used on an industrial scale in TSA units have a physico-chemical structure that can withstand such hydrothermal treatment for a long time; the alumina-type materials are part of it.

 US-A-5232474 describes the use of activated alumina to dry and decarbonate air by a PSA process.

 In any case, obtaining an effective purification of the air stream to be treated in its impurities carbon dioxide and water vapor is not easy, since the purification efficiency depends on many operating conditions.

 Thus, a certain number of parameters or conditions of implementation of the process itself considerably influence the performance of purifications obtained.

 As such, there may be mentioned, in particular, the adsorption temperature and the regeneration temperature.

 Indeed, it is known that adsorption and therefore purification are favored by low temperatures.

 In other words, the lower the temperature, the adsorbent adsorption performance increases.

 From there, it is usually carried out cooling by heat exchange of the compressed gas, that is to say of the air under pressure, leaving the compressor, in general, to a temperature that is typically a few degrees higher than the ambient temperature.

 However, the ambient temperature varies according to the season and it follows that during the so-called hot periods of the year, especially in summer, the effectiveness of the adsorbent will decrease.

 In order to solve this problem, it is possible to regulate the adsorption temperature by means of heat exchanger and one or more refrigerating units in order to keep it substantially constant throughout the year, for example in a given range, which is a function of the subsequent process used, for example a process for the cryogenic distillation of air.

 This solution generates, however, additional investments in equipment, such as heat exchangers, pipelines, refrigeration units, etc.

 Another solution is to oversize the amount of adsorbent used, so as to compensate for these fluctuations of the adsorption temperature and therefore the adsorption performance by a larger amount of adsorbent.

 However, increasing the amount of adsorbent used inevitably implies an increase in process costs.

 Currently, depending on the chosen solution, the adsorption temperature of such an air purification process varies during the year between approximately 50C and 65OC.

 In other words, the performances are very variable during the year for the same purification unit.

 In addition, it is also known that the regeneration temperature of the adsorbent also influences the adsorption efficiency.

 Indeed, the higher the regeneration temperature, the better the regeneration and therefore more effective will be the subsequent purification phase. In general, the regeneration is carried out at a temperature above 1500C.

 However, the higher the regeneration temperature used, the higher the energy consumption of the heater and therefore the process costs increase.

 The regeneration temperature is therefore a parameter to be carefully considered if it is desired to obtain an efficient and economically acceptable purification from the industrial point of view.

 Moreover, it is also essential to take into account the adsorption and desorption pressures used.

 Currently, the adsorption pressure is usually between 4.105 Pa and 60.105 Pa depending on the application.

 Indeed, it is known that a high adsorption pressure promotes the effectiveness of the adsorption of impurities.

 However, the adsorption pressure of an air purification unit situated upstream of a cryogenic distillation column can not be fixed with great freedom, insofar as this depends closely on the characteristics of the cold box of the air separation unit.

 Conversely, the regeneration efficiency increases with the decrease of the regeneration pressure.

 Regeneration of the adsorbent is usually performed by the waste gases, in particular nitrogen or oxygen impure but free of carbon dioxide and water, from the downstream cryogenic distillation unit.

 However, to obtain a flow of waste gas, it is necessary that the pressure of said waste gas is greater than the regeneration pressure in the purification unit containing the adsorbent to be regenerated.

 From there, an increase in the lowest pressure of the cryogenic distillation unit causes an increase in the pressure at the discharge of the air compressor and therefore, consequently, in the compression energy consumption of the entire 'installation.

 Usually, the regeneration pressure is either slightly above atmospheric pressure or below atmospheric pressure; the depression being performed using a vacuum pump.

 In addition, it is known that the adsorption rate also influences the performance of the purification unit.

 However, the adsorption flow rate is imposed by the amount of gas to be produced and therefore varies according to the amount of gas to be produced and the nature of said gas.

 Similarly, the regeneration gas regeneration flow rate used causes fluctuations in adsorption performance.

 In practice, the ratio of the regeneration flow rate to the adsorption rate varies, depending on the process, from 5 to 80%.

 As a result, the higher the ratio, the higher the regeneration performance, but the higher the pressure drop.

 The object of the present invention is to provide a method for purifying gases, in particular air, which leads to an efficient and economically acceptable purification from the industrial point of view, which process is based on a judicious selection of the aforementioned parameters.

 Another aim of the invention is to propose a method making it possible to lead to constant and regular sensible performance throughout the year, that is to say whatever the ambient atmospheric conditions.

The invention thus relates to a method for purifying a gaseous flow containing at least one impurity selected from carbon dioxide (CO2), water vapor (H2O) and hydrocarbons, comprising at least
a step of adsorption of at least one of said impurities on at least one adsorbent bed, said adsorption being carried out at at least one adsorption temperature (Tads) and at least one adsorption pressure (Pads ), and
a regeneration step of at least a portion of said adsorbent bed, said regeneration being carried out at at least one regeneration temperature (Treg) and at least one regeneration pressure (Preg),
characterized by selecting and / or adjusting said adsorption temperature (Tads), said adsorption pressure (Pads), said regeneration temperature (Treg) and said regeneration pressure (Preg) such that
Treg Pads
7.3 <x <33
Tads Preg
Depending on the case, the method of the invention may include one or more of the following features:
Treg Pads
- 10 <x <25
Tads Preg
said adsorption step is carried out, moreover, at an adsorption rate (Dads) and said regeneration step is carried out at a regeneration rate (Dreg) such that:
Treg Pads Dreg
2.8 <xx <14
Tads Preg Dads
Treg Pads Dreg - 3 <xx <12
Tads Preg Dads
the adsorbent is chosen from impregnated activated aluminas, calcined, also called doped aluminas, and exchanged or non-exchanged zeolites, preferably from X zeolites having an Si / Al ratio of less than 1.15 or LSX having a Si / Al ratio; Al of the order of 1;
the gas stream to be purified is air;
- the adsorption pressure is between 3 .105 Pa and 6.106 Pa and / or in that the regeneration pressure is between 105 Pa and 3.105 Pa;
the adsorption temperature is between 0 ° C. and 800 ° C. and / or in that the regeneration temperature is between 20 ° C. and 2000 ° C .;
the ratio of the regeneration flow rate to the adsorption flow rate is between 5% and 808;
a separation is carried out by cryogenic distillation of the purified air obtained;
the process is of the PSA type (Pressure Swing
Adsorption) or TSA type (Temperature Swing
Adsorption), preferably of the TSA type.

 The invention will now be illustrated by means of examples given for illustrative but not limiting.

EXAMPLES
The following examples are intended to compare different operating conditions of a purification process according to the invention, in particular the energy consumption that engenders the regeneration of the adsorbent, as well as the magnitude of the losses of the adsorbent bed charges. .

 In these examples, several adsorbents of different natures were tested, namely 13X type zeolites or LSX (Low Silica X) type having an Si / Al ratio <1.15 and activated and doped aluminas.

 The adsorbent bed is used in a TSA type process implemented in a two adsorber installation operating in parallel, that is to say that one of the adsorbers is in the regeneration phase while the adsorber is in the regeneration phase. other is in purification phase, that is to say adsorption.

 In order to facilitate the comparisons, the cycle time, the adsorption flow rate (Dads), the diameter of the adsorbers, the pressurization and decompression times of the adsorbers are kept constant.

For each test, the ratios RTP and
RDTP, with:
Treg Pads
RTP = x
Tads Preg
and Treg Pads Dreg Dreg
RDTP = xx = RTP x
Tads Preg Dads Dads
The test conditions and the results obtained for each of the tests A to D were recorded in the following Table I.

TABLE I

<tb> TEST <SEP> Tads <SEP> Treg <SEP> Pads <SEP> Preg <SEP> Dads <SEP> RTP <SEP> RDTp <SEP> Result
<tb><SEP> 5 <SEP> 5 <SEP>
<tb><SEP> N <SEP> (c) <SEP> (c) <SEP> (105 <SEP> Pa) <SEP> (105 <SEP> Pa) <SEP> Dreg <SEP> Global
<tb><SEP> A <SEP> 10 <SEP> 200 <SEP> 6 <SEP> 1,1 <SEP> 25% <SEP> 109 <SEP> 27,3 <SEP>
<tb><SEP> B <SEP> 40 <SEP> 70 <SEP> 3 <SEP> 1,1 <SEP> 15% <SEP> 4,77 <SEP> 0,72 <SEP>
<tb><SEP> C <SEP> 12.5 <SEP> 60 <SEP> 6 <SEP> 1,1 <SEP> 18% <SEP> 4,6 <SEP> 26,2 <SEP> +
<tb><SEP> D <SEP> 24 <SEP> 160 <SEP> 65 <SEP> 1,1 <SEP> 26% <SEP> 9.3 <SEP> 36.4 <SEP> +
<Tb>
It is apparent from Table I above that tests A and B lead to poor results, while tests C and D give good results.

 More precisely, in the A-test, the regeneration temperature (Treg) is very high, which leads to a waste of energy, that is to say to an overconsumption of energy.

 Conversely, in test B, the regeneration temperature used is not high enough to ensure efficient regeneration of the adsorbent bed.

In this case, impurities adsorbed during the purification phase will not be completely desorbed during the regeneration phase.

 In tests C and D, in accordance with the present invention, it is found that, for well-chosen operating conditions, favorable results are obtained both with regard to the purification performance of the air thus treated, as well as concerns the particular energy costs, namely compression energy and regeneration energy for example.

Table II below gives values of adsorption pressures (Pads) and regeneration temperature (Treg) according to the present invention (here TPDR is between about 3 and 12), for an adsorption temperature (Tads). ), a regeneration pressure (Treg) and a flow ratio (Dreg / Dads) constant, namely: Tads = 200C, Preg = 1.1.10 Pa and
Dreg / Dads = 10%. For these values, the adsorbent used may in particular be a type X zeolite, preferably of the LSX type, exchanged or not, or an activated alumina, doped or otherwise.

TABLE II

<tb><SEP> Pads <SEP> Treg <SEP> (cc) <SEP>
<tb><SEP> 5 <SEP>
<tb> (10 <SEP> Pa) <SEP> 40 <SEP> | <SEP> 50 <SEP> 80 <SEP>. <SEP> 100 <SEP> 125 <SEP> 150 <SEP> 175 <SEP> 200
<tb><SEP> 4 <SEP> 3.2 <SEP> 3.6
<tb><SEP> 5 <SEP> | <SEP> 3,4 <SEP> 4 <SEP> 4,5
<tb><SEP> 6 <SEP> 3.4 <SEP> 4.1 <SEP> 4.8 <SEP> 5.5
<tb><SEP> 8 <SEP> | <SEP> 3.6 <SEP> 4.5 <SEP> 5.5 <SEP> 6.4 <SEP> 7.3
<tb><SEP> 10 <SEP> 3.6 <SEP> 4.5 <SEP> 5.7 <SEP> 6.8 <SEP> 8 <SEP> 9.1
<tb><SEP> 12 <SEP> 4.4 <SEP> 5.5 <SEP> 6.8 <SEP> 8.2 <SEP> 9.5 <SEP> 10.9
<tb><SEP> 15 <SEP> 3.4 <SEP> 5.5 <SEP> 6.8 <SEP> 8.5 <SEP> 10.2 <SEP> 11.9
<tb><SEP> 30 <SEP> 5.5 <SEP> 6.8 <SEP> 10.9
<Tb>
It follows that the implementation of a high performance adsorbent, such as an X or LSX zeolite or a doped activated alumina, under the operating conditions according to the present invention can significantly reduce the energy consumption.

 In addition, with equivalent adsorption performance, the process according to the invention makes it possible to reduce the quantity of adsorbent to be used, therefore the pressure losses within the adsorption bed and the compression energy to be used, and to obtain a transit time of the adsorption bed by the shorter heat front during the regeneration phase and thus a more efficient regeneration and less expensive energy.

Claims (10)

 A process for purifying a gas stream containing at least one impurity selected from carbon dioxide, water vapor and hydrocarbons, comprising at least  a step of adsorption of at least one of said impurities on at least one adsorbent bed, said adsorption being carried out at at least one adsorption temperature (Tads) and at least one adsorption pressure (Pads ), and  a regeneration step of at least a portion of said adsorbent bed, said regeneration being carried out at at least one regeneration temperature (Treg) and at least one regeneration pressure (Preg),  characterized in that said adsorption temperature (Tads), said adsorption pressure (Pads), said regeneration temperature (Treg) and said regeneration pressure (Preg) are selected such that  Treg Pads  7.3 <x <33  Tads Preg  2. Method according to claim 1, characterized in that  Treg Pads  10 <x <25  Tads Preg  3. Method according to one of claims 1 or 2, characterized in that said adsorption step is carried out, in addition, at an adsorption rate (Dads) and said regeneration step is carried out at a regeneration rate ( Dreg) such as:  Treg Pads Dreg  2.8 <x x <14  Tells Preg DadKs  4. Method according to claim 3, characterized in that  3 <Treg. Pads. Last <12  Tads Preg Dads  5. Method according to one of claims 1 to 4, characterized in that the adsorbent is selected from impregnated activated aluminas, calcined and exchanged or non-exchanged zeolites, preferably from zeolites X having an Si / Al ratio. less than 1.15 or LSX zeolites having an Si / Al ratio of about 1.  6. Method according to one of claims 1 to 5, characterized in that the gas stream to be purified is air.  7. Method according to one of claims 1 to 6, characterized in that the adsorption pressure is between 3.105 Pa and 6.106 Pa and / or in that the regeneration pressure is between 105 Pa and 3.105 Pa.  8. Method according to one of claims 1 to 7, characterized in that the adsorption temperature is between 0 C and 800C and / or in that the regeneration temperature is between 20 "C and 2000C.  9. Method according to one of claims 1 to 8, characterized in that the ratio of the regeneration flow rate adsorption rate is between 5% and 80%.  10. Method according to one of claims 1 to 9, characterized in that it is selected from VSA or TSA methods.