EP3105520A2 - Column for separating air by cryogenic distillation, air separation device comprising such a column and method for producing such a column - Google Patents

Abstract

The invention relates to a column (2) for separating air by means of cryogenic distillation, said column comprising a shell and at least four distillation segments (24, 25, 26, 27, 28), including at least a first intermediate distillation segment (25) of the low-pressure column, which is surrounded by an auxiliary shell around which a space is defined that is divided into a lower section and an upper section along the radius of the column, the intermediate segment(s) being located in an intermediate part of the low-pressure column, the capacity of the first intermediate segment being greater than that of at least one adjacent segment (24, 26), and an opening being disposed in the shell between two adjacent segments, which opening can be sealed if the column is to form part of an argon production device.

Description

 Cryogenic distillation air separation column, air separation apparatus comprising such a column and method of

 manufacture of such a column

The present invention relates to an air separation column by cryogenic distillation, to an air separation apparatus comprising such a column and to a method of manufacturing such a column.

 It is sometimes necessary to modify the drawings of an air separation unit under design, depending on a change in the customer's needs. For example, the customer may find that he will need argon production when the unit is already designed without argon production, or even exists without argon column.

 One way to solve this problem is to design the apparatus with a column capable of producing argon but which discharges the purged gas into argon in the residual nitrogen when argon is not required. It is also possible to increase the dimensions of the low pressure column. Both solutions require higher investment costs.

 An air distillation plant for the production of argon generally consists of a medium pressure column, typically operating at about 6 bar absolute, surmounted by a low pressure column typically operating slightly above atmospheric pressure and which is coupled an impure argon production column. A condenser-vaporizer puts in heat exchange relationship the steam of the head of the medium pressure column, consisting of approximately pure nitrogen, and the bottom liquid of the low pressure column, consisting of approximately pure oxygen.

The low pressure column comprises a distillation section, immediately above it, a first intermediate distillation section, and several sections above the first section. intermediate distillation, usually between two and three.

 Each of the distillation sections consists of structured packing blocks of the "cross-corrugated" type.

 As is well known, a cross-corrugated packing block consists of a pack of corrugated lamellae each arranged in a general vertical plane and contiguous to each other, each lamella having a generally rectangular shape. The lamellae are corrugated obliquely, and the direction of inclination of the waves is reversed from one lamella to the next. All lamellae have the same height, while their length, or horizontal dimension, increases from a minimum value, for an extreme lamella, to a maximum value for the medial lamella, then decreases to the same minimum value for the lamellae. other extreme lamella.

 Each of the sections is a continuous lining section, that is to say a section consisting of a direct stack of elementary blocks on top of each other, without any intermediate fluid redistribution device, each elementary block being rotated 90 °, around the axis of the column, with respect to the two adjacent layers.

The first intermediate distillation section, as described in EP-A-0664144, has a smaller section than the other sections and is therefore in the middle of the low pressure column with an annular section space between the edge of the section and the main ferrule of the column. The column is designed so that the argon-rich vapor can be withdrawn into this annular section space below a slug which divides the space into a lower section and an upper section vertically. This steam then feeds the argon column. The bottom liquid of the argon column is also returned to the lower section from which the richest argon vapor is withdrawn. The vaporized rich liquid from the top condenser of the argon column is sent in the upper section of the space.

 The first intermediate distillation section is separated from the adjacent sections by distributors.

 Thus the rackings and the supply of gas in the column, related to the argon production, do not add to the height of the column.

 The reduced diameter for this first intermediate distillation section is possible, without increasing the diameter of the column because this section is not dimensioning. Indeed, a large amount of gas passes to the argon column and therefore does not pass through this section.

 When the plant is designed not to produce argon, this section with reduced section is not installed, according to the prior art.

 One of the aims of the present invention is to design a low pressure column which is suitable for production with or without argon. The idea is to use a column with first reduced section intermediate distillation section, with or without argon production, and to modify the density of the packing in this section, with a lower density for the case without production of argon and a higher density for the case with argon production.

 The invention makes it possible to have a standardized model for the low pressure column, with or without production of argon. This also makes it possible to standardize the architecture of the cold box, including the fluid supply lines. The delivery time to the customer can be reduced because it is possible to manufacture the column before deciding on the need for argon production or not.

 It is known to increase the capacity of a lining section by modifying the geometry of the packings, as described in EP-A-0707885.

According to one object of the invention, there is provided a cryogenic distillation air separation column having a ferrule and at least one four distillation sections, each section being composed of a stack of stacked packing units of the wavy-cross type, each block comprising a pack of rectangular wavy lamellae, at least a first intermediate distillation section of the column being surrounded by an auxiliary shell around which is delimited a space divided into a lower section and an upper section in the direction of the radius of the column, the intermediate section (s) being located in an intermediate part of the column characterized in that the capacity of the first intermediate section is greater than that of at least one adjacent section, or even that of the other sections of the column and that a second and a third intermediate distillation section are arranged so that in use the second section is above the first intermediate section and the third section is above of the second intermediate section and comprising a first opening in the space between the first and the second intermediate section, a second opening in the space between the second and third intermediate section and a third opening in the space above the third section, the first, second and third openings being adapted to be connected to a liquid supply line, the first or the third opening being locked and the second opening being open.

 According to another optional object of the invention, the column comprises:

- openings in the shell intended to connect the upper section and the lower section with the outside of the column which have been condemned

 - The lining in the first intermediate section has a density of at least 50 m2 / m3 less than that of at least one of the adjacent sections.

 - The lining in the first intermediate section has a different geometry to that of at least one of the adjacent sections.

According to another object of the invention, there is provided a air separation comprising a medium pressure column thermally connected to a low pressure column as described above not comprising means for sending a fluid from an intermediate level of the low pressure column to another column to be separated therefrom.

 According to another object of the invention, there is provided a method of manufacturing a column of an air separation apparatus in which a column having a main shell is constructed and several distillation sections are installed, each section being composed of a stack of stacked packing blocks of the wavy-cross type, each block comprising a pack of rectangular wavy lamellae, at least a first intermediate distillation section of the low-pressure column being surrounded by an auxiliary ferrule around which is delimited a space divided into a lower section and an upper section in the direction of the radius of the column, the intermediate section (s) being located (s) in an intermediate portion of the low pressure column characterized in that

 i) if the column is to be part of an apparatus not producing an argon-rich flow, a packing is installed for the first intermediate section, the packing being chosen so that the capacity of the first intermediate section is greater than that of ) at least one adjacent section, or even to that (s) of the other sections of the column and at least one reflux opening is pierced in the main shell at a point between two adjacent sections, at a level between the first intermediate section and the head of the column and

 (ii) if the column is to be part of an apparatus producing a high argon flow, the reflux opening is obstructed.

 According to other optional aspects:

at least one aperture is pierced in the main ferrule allowing access to the lower section and / or the upper section and at least one opening is closed in the case where the column has to make part of a device that does not produce a flow rich in argon.

 at least one reflux opening is pierced in the main shell at a point between two adjacent sections at a level between the first section and the top of the column and the reflux opening is obstructed if the column is to be part of a device that does not produce a flow rich in argon.

 at least one reflux opening is pierced in the main shell at a point between two adjacent sections at a level between the first section and the top of the column and the reflux opening is obstructed if the column is to be part of a device producing a flow rich in argon.

 The term "rich liquid" as used herein is a term of the art for designating an oxygen enriched liquid with respect to air.

 In general, it is interesting to design a standardized version of the medium pressure column and the bottom of the low pressure column (at least one section), whatever the required products and to design the rest of the low pressure column. according to customer needs

 Embodiments of the invention will now be described with reference to the accompanying drawings, in which:

 - Figure 1 schematically shows a low pressure column of an air distillation apparatus according to the invention adapted for use without argon production

 - Figure 2 schematically shows a low pressure column of an air distillation apparatus according to the invention adapted for use with argon production

The air distillation plant whose low pressure column is shown in Figure 1 consists of a medium pressure column 1, typically operating at about 6 bar absolute, surmounted by the low pressure column 2 typically operating slightly above atmospheric pressure. The absence of any impure or pure argon production column is noted. A condenser-vaporizer 4 connects the overhead steam of the column 1, composed of approximately pure nitrogen, to the heat exchange medium, and the bottom liquid of the column 2, consisting of approximately pure oxygen.

 Column 1 receives pressurized and purified air to be separated and produces an oxygen enriched liquid flow and a nitrogen enriched liquid flow, both of which are sent to the low pressure column 2.

 The illustration of Figure 1 is very schematic and is essentially intended to show the fluid inlets / outlets of the installation, as well as the distillation sections that they define.

 The main shell of the low pressure column 2 comprises six distillation sections, namely:

 A lower distillation section 24 between the column vessel and its liquid outlet 10 and the first intermediate distillation section 25

 • immediately above the section 24 with a distributor (not shown) in between, the first intermediate distillation section 25 below the liquid inlet 6, the section of the first intermediate distillation section being lower than that of the lower section

 A second intermediate distillation section 26 between the first and third intermediate distillation sections

A third intermediate distillation section 27 between the second intermediate section and an upper distillation section 28,

 An upper distillation section 28 between the third intermediate distillation section and a section of minaret

• the section of mid naret 29 that has a lower section than the upper disti llation section. The section of the first intermediate distillation section being lower than those of the lower section, the upper section and the second and third intermediate sections. Section 29 is shown in dotted lines because its presence is not essential.

 The first intermediate portion 25 is a cylindrical body composed of packings surrounded by an auxiliary ferrule of smaller diameter than the ferrule of the column. It is disposed inside the shell of the column and surrounded by an annular section space defined by the ferrule of the column and the auxiliary shell surrounding the packings. An annular sealing member 71 tightly connects the ferrule of the column and the auxiliary shell, and the top of the section 26 is spaced from the distributor 29C by spacers 72.

 Each of the distillation sections 23 to 29 is constituted by organized packing blocks of the "cross-corrugated" type.

 As is well known, a cross-corrugated packing block consists of a pack of corrugated lamellae each arranged in a general vertical plane and contiguous to each other, each lamella having a generally rectangular shape. The lamellae are corrugated obliquely, and the direction of inclination of the waves is reversed from one lamella to the next. All lamellae have the same height, while their length, or horizontal dimension, increases from a minimum value, for an extreme lamella, to a maximum value for the medial lamella, then decreases to the same minimum value for the lamellae. other extreme lamella.

Each of the sections 23 to 29 is a section of continuous packing, that is to say a section consisting of a direct stack of layers (in English "packs") elementary on each other, without any device for redistribution of intermediate fluid, each elemental layer being rotated 90 °, about the axis of the column, relative to the two adjacent layers. This is rendered possible, despite the great height of some sections, including sections 23, 24 and 28, which may comprise respectively 40, 38 and 50 theoretical trays, thanks to several features that will appear in the following.

 Distillation sections 24 and 25, on the one hand, 25 and 26, on the other hand, 26 and 27, 27 and 28, finally 28 and 29, are separated from each other by a distributor.

 While the low pressure column is not intended to be connected to an argon column, it nevertheless contains the reduced section section which is generally used for low pressure columns feeding an argon column.

 While in a low pressure column feeding an argon production column, the packings used for the five sections 24 to 28 are identical, the packings used for the first intermediate section 25 are less dense than those of the sections 24, 26, 27. , 28 and possibly 29. The presence of the section 29 is not essential.

 This means that in constructing the column, the decision of the lining capacity to be installed in the first intermediate section can be taken very late, as soon as the decision is made to produce argon or not. The main ferrule and the external connections can be manufactured and only the installation of the section 25 determines the ultimate use that will be made of the column 2.

 In order to modify the packing capacity of the section 25, several possibilities open. As proposed in EP-A-0707885, it is possible to modify the edges of the lining section in order to reduce the resistance to the passage of gas in the lower and / or upper portion of the section relative to the inside of the section.

It is also possible to choose a lighter packing of at least 50 m ² / m ³ for the section 25 than for the sections 24 and 26. Thus the lining for the section 25 may have a medium density of 350 m ² / m ³ while the average density of the packings for the sections 24 and 26 will be 500 m ² / m ³ .

 The aim is to choose, for the case without argon, a section which has a higher waterlogging limit than for the case with argon. This difference in limit can be obtained by various means, for example by choosing sections made of packings of different geometries, with or without a modified low edge to reduce the resistance to the passage of gases, etc.

 Between the first and the second intermediate section, a rich liquid inlet (liquid enriched in oxygen) is provided. Upstream of the column, the liquid is expanded to partially vaporize and it is a liquid flow 6 and a gas flow 6A that are sent to the space between the two sections.

 Between the second and third intermediate sections, a liquefied air supply is planned. Upstream of the column, the liquid is expanded to partially vaporize and it is a liquid flow 8 and a gas flow 8A that are sent to the space between the two sections.

 Between the upper section 28 and the minaret section 29 (optional), a liquid nitrogen inlet 17 is provided and a liquid nitrogen inlet 18 at the minaret section head. In the absence of a minaret, liquid nitrogen is sent to the top of the column.

 Figure 1 thus illustrates the standardized column 2 connected to operate as the low pressure column of a double column without argon production.

If it is decided to use the same column 2 to be the column supplying an argon production column, the packings of the section 25 will have the same density as those of the sections 24, 26, 27, 28 and possibly 29 (by example 500 m ² / m ³ ). However, it will be necessary to provide openings in the column as shown in Figure 2. The inside of the column will therefore be identical to that of FIG. 1 except for the capacity of the section 25. At the section 25, a pipe is connected to the lower section below the barrier 71 to bring an argon-enriched gas. to the argon separation column. The bottom liquid of this column arrives in the lower section via line 21. The rich liquid vaporized in the top condenser of the argon column arrives through line 13 in the upper section.

 For the reflux flow rates, the rich liquid 6 and the vaporized rich liquid 6A arrive between the second and third intermediate sections 26, 27 and the liquefied air 8 and the vaporized liquefied air 8A arrive between the third intermediate section 27 and the section 28. The arrivals of nitrogen are identical to those of Figure 1.

 Thus, before knowing whether the column 2 will be used to produce argon or not, openings may be formed between the first and second intermediate sections 25, 26, the second and third intermediate sections 26, 27 and between the third intermediate section 27. and the upper section 28. The column is thus manufactured with openings allowing the subsequent connection of fluid conduits for or coming from the argon column and also those allowing the connection to the medium pressure column in the case of argon production or not.

 A full flange, or other system will then be used to condemn unused inputs and outputs in the case of argon-free production and to condemn other unused inputs and outputs in the case of argon production.

In the case of argon production, the opening between the first and second intermediate sections 25, 26 will be plugged, the opening between the second and third intermediate sections 26, 27 will allow the arrival of rich liquid and between the third section intermediate 27 and the upper section 28 of liquefied air.

 In the absence of argon production, the opening between the first and second intermediate sections 25, 26 will allow the arrival of rich liquid, the opening between the second and third intermediate sections 26, 27 will allow the arrival of liquefied air and the opening between the third intermediate portion 27 and the upper section 28 of air will be clogged.

 It is possible, however, that there are other differences between column 2 designed for argon production and column 2 designed not to produce argon. In particular, the type or dimensions of the dispensers may vary from one column to another.

Claims

claims

Cryogenic distillation air separation column (2) having a ferrule and at least four distillation sections (24, 25, 26, 27, 28, 29), each section being composed of a stack of packing blocks arranged, cross-corrugated type, each block comprising a pack of rectangular corrugated lamellae, at least a first intermediate portion (25) for distillation of the column being surrounded by an auxiliary ferrule around which is delimited a space divided into a section lower and an upper section in the direction of the radius of the column, the intermediate section (s) being located (s) in an intermediate portion of the column characterized in that the capacity of the first intermediate section is greater than that (s) ) of at least one adjacent section, or even that of the other sections of the column and in that it comprises a second and a third intermediate distillation section arranged in such a way that in use the second intermediate section (26) is above the first intermediate section and the third intermediate section (27) is above the second intermediate section and comprising a first opening in the space between the first and second second intermediate sections, a second opening in the space between the second and third intermediate sections and a third opening in the space above the third section, the first, second and third openings being adapted to be connected to a pipe; arrival of liquid, the first or the third opening being condemned and the second opening being open.

2. Column according to claim 1 comprising openings in the shell adapted to connect the upper section and the section lower with the outside of the column that have been condemned.

3. Column according to one of the preceding claims wherein the lining in the first intermediate portion (25) has a density at least 50 m ² / m ³ less than that of at least one of the adjacent sections (24, 26). ).

4. Air separation apparatus comprising a medium pressure column (1) thermally connected to a low pressure column (2) according to one of claims 1 to 3 not comprising means for sending a fluid of an intermediate level of the low pressure column to another column to be separated.

A method of manufacturing a column (2) of an air separation apparatus in which a column having a main ferrule is constructed and a plurality of distillation sections (24, 25, 26, 27, 28, 29), each section being composed of a stack of stacked packing units of the wavy-cross type, each block comprising a packet of rectangular wavy lamellae, at least a first intermediate portion (25) of distillation of the low pressure column being surrounded an auxiliary ring around which is delimited a space divided into a lower section and an upper section in the direction of the radius of the column, the intermediate section (s) being located in an intermediate portion of the column low pressure characterized in that

i) if the column is to be part of an apparatus not producing an argon-rich flow, a packing is installed for the first intermediate section, the packing being chosen so that the capacity of the first intermediate section is greater than that of ) of at least one adjacent section (24,26), even to that (s) of the other sections of the column and at least one reflux opening is pierced in the ferrule at a point between two adjacent sections, at a level between the first intermediate section and the top of the column and

 (ii) if the column is to be part of an apparatus producing a high argon flow, the reflux opening is obstructed.

6. The method of claim 5 wherein is pierced at least one opening in the main shell allowing access to the lower section and / or the upper section and the at least one opening is closed in the case where the column must make part of a device producing no argon-rich flow.