FR3069915A1 - APPARATUS AND METHOD FOR AIR SEPARATION BY CRYOGENIC DISTILLATION - Google Patents

Abstract

Process for the separation of air by cryogenic distillation in which at least a portion of the air to be distilled in an air booster (C2) is overpressed, in at least one expansion turbine (T2, T1) is depressed compressed air and if the pressure drop between two points of the booster goes below a threshold and / or a flow rate of the booster goes below a minimum flow of the booster, it relaxes some of the air boosted in the booster without having cooled between the booster and the expansion and the expanded compressed air is sent upstream or downstream of the at least one turbine, without having been cooled in the heat exchanger after being overpressed.

Description

The present invention relates to an apparatus and a method for separating air by cryogenic distillation. It relates in particular to devices using a supply air supercharger supplied with air coming from an intermediate level of a main supply air cooling exchanger, therefore at a temperature below 0 ° C. . This air is then boosted in the booster and returned to the main exchanger before being sent to a cryogenic distillation column.

When the pressure difference between the inlet and the outlet of a compressor becomes too high, instabilities called separations appear at the compressor blades. The aerodynamic stall no longer pushes the air in the right direction, and the "high pressure" part of the compressor (the outlet) empties into its "low pressure" part (the inlet). In some extreme cases, a reversal of the direction of flow may even occur.

These large flow fluctuations are called pumping, due to the nature of this phenomenon of aerodynamic instability, which gives rise to longitudinal waves. If, by increasing the speed of rotation, the pressure difference between the inlet and the outlet of a compressor increases, this increase in pressure is limited by this pumping phenomenon. When the compression ratio exceeds a critical value, pumping occurs and the increase in the speed of rotation of the compressor will have almost no influence on the compression ratio.

If this phenomenon levels the performance of the compressors, it is also sometimes very destructive for the compressors.

Generally when the approach to pumping is detected, part of the compressed air is returned to the compressor upstream of the compressor after refrigeration followed by expansion in a valve.

In the case of a cold booster, in order to reduce costs, it is desirable to remove the refrigerant downstream of the overpressure and upstream of the heat exchanger.

One could consider returning the compressed air in the cold booster to the own suction in case of pumping and cooling the pressurized air to return to the suction in dedicated passages of the heat exchanger, but this solution risks be expensive by complicating the exchanger.

The present invention solves the problem by opening a valve to a turbine downstream of the compressor, in order to increase the flow rate in the compressor and thus leave the pumping area.

According to an object of the invention, there is provided an air separation apparatus by cryogenic distillation comprising an air compressor to compress all the air to be distilled, an air booster to compress at least part of the air to be distilled, an expansion turbine to receive compressed air from the compressor and possibly from the air booster, a system of cryogenic distillation columns comprising at least one column, a heat exchanger, means for sending air air from the compressor to the heat exchanger having two ends, means for withdrawing cooled air at an intermediate point of the heat exchanger between the two ends and for sending to the booster means for sending compressed air from the booster to the heat exchanger, means for sending cooled air in the heat exchanger to the turbine, means for sending expanded air in the column system turbine, means for withdrawing from the column system a flow enriched in oxygen and a flow enriched in nitrogen, these means being connected to the heat exchanger characterized in that it comprises means for relaxing the compressed air in the booster, in that it does not include any means of cooling between the discharge of the booster and the means for relieving the boosted air and in that it comprises means for sending air, boosted in the booster and expanded by the expansion means, upstream or downstream of the turbine, without having been cooled in the heat exchanger after being overpressed.

According to other optional aspects:

the apparatus comprises means for detecting the pressure drop or the flow between two points of the booster as well as means for opening the expansion means, for example a valve, for sending the compressed air upstream or downstream of the turbine without going through the heat exchanger depending on the pressure drop or the flow rate of the booster.

the booster is connected to the turbine inlet so that the boosted air can at least partially relax in the turbine.

According to another aspect of the invention, there is provided a method of air separation by cryogenic distillation in which all the air to be distilled is compressed in an air compressor, at least part of the air is pressurized to compressed distiller in the air compressor in an air booster, the compressed air from the compressor and possibly the air booster is expanded in at least one expansion turbine, the compressed air cooled in a heat exchanger in a system of cryogenic distillation columns comprising at least one column, air cooled is taken from an intermediate point of the heat exchanger between its two ends to send to the booster, air is boosted from the booster to the heat exchanger, we send cooled air in the heat exchanger to the turbine, we send expanded air in the turbine to the column system, we support ire from the column system a flow enriched in oxygen and a flow enriched in nitrogen and these flows are reheated in the heat exchanger, characterized in that if the pressure drop between two points of the booster passes below a threshold and / or a flow rate of the booster passes below a minimum flow rate of the booster, part of the compressed air is relaxed in the booster without having cooled it between the booster and the expansion valve and the expanded compressed air is sent upstream or downstream of the at least one turbine, without having been cooled in the heat exchanger after having been boosted.

According to other optional aspects:

if, preferably only if, the pressure drop between the two points is above the threshold and / or a flow rate of the booster passes (above the minimum flow rate of the booster, all the air from the booster is sent to the heat exchanger heat to cool.

if the pressure drop between the two points of the booster passes below the threshold and / or a flow of the booster falls below the minimum flow of the booster), no part of the compressed air is sent upstream of the booster.

supercharged and expanded air is expanded in the turbine if the pressure drop between the two points of the booster passes below the threshold (and / or a flow rate of the booster passes below the minimum flow rate of the booster and preferably no flow d air from the booster is only expanded in the turbine if the pressure drop between the two points of the booster is above the threshold and / or a flow rate of the booster passes above the minimum flow rate.

if the pressure drop between the two points of the booster passes below the threshold (and / or a flow rate of the booster passes below the minimum flow), the compressed air is expanded until the pressure of a column of the columns, is mixed with the air from the turbine and is sent to the column.

the separation process is carried out in a separation device by cryogenic distillation.

if the pressure drop between the two points of the booster is above the threshold or the flow rate of the booster is above the minimum flow rate, all the boosted air is sent to cool in the heat exchanger.

the expanded compressed air sent to the turbine is sent to a turbine coupled to the booster from which the air comes.

the expanded compressed air sent to the turbine is sent to a turbine receiving air, or all the air it expands, from the booster.

the turbine receives air from the booster only if the pressure drop between the two points of the booster is below the threshold.

if the pressure drop between two points of the booster passes below a threshold and / or a flow rate of the booster passes below a minimum flow rate of the booster, part of the air supercharged in the suppressor is expanded by means other than a turbine.

if the pressure drop between two points of the suppressor falls below a threshold and / or a flow rate of the suppressor falls below a minimum flow rate of the suppressor, part of the air supercharged in the suppressor is expanded in a valve .

if the pressure drop between two points of the suppressor falls below a threshold and / or a flow rate of the suppressor falls below a minimum flow rate of the suppressor, part of the air supercharged in the suppressor is relaxed until an inlet or outlet pressure of a turbine of the device, or even up to the pressure of a column of the device.

the air suppressor has an inlet temperature between 0 ° C and -180 ° C, or even between -60 ° C and-180 ° C.

The invention will be described in more detail with reference to the figure which illustrates an air separation apparatus by cryogenic distillation according to the invention.

The apparatus comprising a column system comprising a column operating at a first pressure K1 and a column operating at a second pressure K2 lower than the second pressure. The columns are thermally connected through a tank reboiler of the second column heated by nitrogen from the top of the first column. Non-illustrated reflux flows enriched in nitrogen and oxygen are sent from column K1 to column K2. Liquid oxygen 31 is drawn off from the tank of the second column K2 and nitrogen gas 33 is drawn off at the top of the second column. LIN liquid nitrogen is sent to the top of the second column in certain stages to help keep the process cool. An oxygen-rich fluid is sent to heat up at the exchanger E, for example liquid oxygen 31 can vaporize in the heat exchanger E. A nitrogen-rich fluid is sent to heat up at the exchanger E.

The apparatus comprises a first air expansion turbine T1, a second air expansion turbine T2, a first air blower C1 coupled to the first turbine and a second air blower C2 coupled to the second turbine.

The compressed air 1 at a pressure P coming from another compressor (not illustrated) is divided into two fractions, a first fraction 3 of which is sent to the heat exchanger E without having been compressed to a pressure beyond the pressure P. A second fraction 5 is sent to the first booster C1 where it is compressed to a pressure higher than that (P) of the first fraction 3. The outlet of the first booster C1 is connected to the inlet of this booster by a pipe 25 through a V8 valve.

According to a first variant, the first fraction 3 is cooled in the heat exchanger E to an intermediate temperature thereof and not having been compressed in the first booster is sent to the first and the second turbines through the open valve CL3 and the open valves V5, V13, V4, V19.

The second fraction 5 cools in the heat exchanger E to an intermediate temperature thereof after being compressed in the first booster C1. Then it is sent to the second booster C2.

In normal operation, the expanded air from the first and second turbines is sent to the first column K1 to be separated through the valves V6, V15, V11 and the pipe 13. The second fraction 5 is compressed in the second booster C2, passes through the open valve CL1 and then cools in the heat exchanger before being sent in liquid form to the first column K1 through the valve V9. Valves V2 and V3 are closed.

If the booster C1 approaches its pumping point, part of the boosted air is taken after cooling in a cooler downstream of the booster, expanded by the valve V8 and returned to the suction of the booster C1.

If the booster C2, supplied with air 19 coming from an intermediate point of the heat exchanger E, approaches its pumping point, no part of the air boosted in the booster C2 is sent at the suction of the C2 booster. The C2 booster has no refrigerant downstream of the booster. If the boosted flow in C2 falls below a threshold indicating that the pumping point is close, a portion of the boosted air is sent via line 23, expanded in valve V3 and arrives at the suction of the turbine. T2 to be relaxed and sent to distillation.

The threshold for detecting the approach to the pumping point is defined by defining a pressure drop threshold between two points of the booster not to be exceeded. As long as the pressure drop remains below the threshold, all the compressed air is sent to the heat exchanger to liquefy there.

Once the pressure drop has reached the threshold, the valve is opened allowing air to pass to the turbine.

The rest of the pressurized air is returned to the heat exchanger E through the valve CL1 and at least partially liquefies in the exchanger before being expanded in the valve V9 and sent to the column K1.

Alternatively, the part of the air sent to the inlet of the turbine T2 can be sent to the outlet of the latter arriving in the pipe 17. In this case, the air expansion valve will relax this part of the air up to a pressure slightly above the pressure of column K1.

It is also possible to send the air part not to the T2 turbine but to the inlet or outlet of the T1 turbine. Air can even be sent to the two turbines T1, T2, the inlets of the two, the outlets of the two or the inlet of one and the outlet of the other.

According to a second variant, the first fraction 3 exits from a heat exchanger at an intermediate temperature thereof and, not having been compressed in the first booster, is sent to the second booster C2.

The second fraction 5 cools in the heat exchanger to an intermediate temperature thereof after being compressed in the first booster C1. Then it is sent to the first and second turbines.

In this case also if the booster C2, supplied with air 19 coming from an intermediate point of the heat exchanger E, approaches its pumping point, no part of the air boosted in the booster C2 is not sent to the suction of the C2 booster. The C2 booster has no refrigerant downstream of the booster.

If the boosted flow in C2 falls below a threshold indicating that the pumping point is close, a portion of the boosted air is sent via line 23, expanded in valve V3 and arrives at the suction of the turbine. T2, without passing through the exchanger E, to be expanded in the turbine T2 and sent to distillation.

The threshold for detecting the approach to the pumping point is defined by defining a pressure drop threshold between two points of the booster not to be exceeded. This pressure difference is equivalent to the minimum air flow in the booster under which it must not pass. As long as the pressure drop remains above the threshold, all the compressed air is sent to the heat exchanger to liquefy there.

Once the pressure drop falls below the threshold, the valve is opened allowing air to pass to the turbine.

It is also possible to trigger the opening of the valve if the air flow rate in the booster drops below a threshold.

The rest of the pressurized air is returned to the heat exchanger E through the valve CL1 and at least partially liquefies in the exchanger before being expanded in the valve V9 and sent to the column K1.

Alternatively, the part of the air sent to the inlet of the turbine T2 can be sent to the outlet of the latter arriving in the pipe 17. In this case, the air expansion valve will relax this part of the air up to a pressure slightly above the pressure of column K1.

It is also possible to send the air part not to the T2 turbine but to the inlet or outlet of the T1 turbine. Air can even be sent to the two turbines T1, T2, the inlets of the two, the outlets of the two or the inlet of one and the outlet of the other.

An oxygen-rich fluid is sent to heat up at the exchanger E, for example liquid oxygen 31 can vaporize in the heat exchanger E. A nitrogen-rich fluid is sent to heat up at the exchanger E.

The invention also applies to the case in which the device comprises only a single air turbine coupled to a cold booster.

In this case, the air is sent in normal service from the cold booster to the heat exchanger. The air can then pass directly into the column system after expansion or otherwise can be sent at least in part to the single turbine.

In the case where part of the compressed air is liquefied in the heat exchanger and is expanded in a valve V9 upstream of the column system, when the flow of compressed air in the C1 booster passes below a threshold indicating the approach to pumping, the liquid flow passing through the valve V9 can be increased. This valve will then be sized for this operating case.

It will be understood that the device may comprise a single cold booster and a single turbine, whether or not receiving air from the cold booster outside of the pumping risk period.

This invention applies to any process using a cold air blower 15 in an apparatus for separating air by cryogenic distillation. It applies for example to the methods of FR2943408, WO05064252, EP2831525,

JP2015114083, JP54162678, EP1055894, EP2600090, JP2005221199,

EP2963370, EP2963369, FR2913670, FR3033397, EP2458311, EP1782011, EP1711765, FR2895068, EP2489968, DE102011121314, EP1014020,

FR2985305, DE102006027650, FR2861841, FR3010778, EP644388 and

FR2721383.

The air blower preferably has an inlet temperature between 0 ° C and -180 ° C, or even between -60 ° C and -180 ° C.

Claims (12)

claims 1. Apparatus for air separation by cryogenic distillation comprising an air compressor to compress all the air to be distilled, an air booster (C2) to compress at least part of the air to be distilled, a turbine for expansion (T1, T2) to receive compressed air from the compressor and possibly the air booster, a system of cryogenic distillation columns comprising at least one column (K1, K2), a heat exchanger (E), means for sending air from the compressor to the heat exchanger having two ends, means (19) for taking cooled air at an intermediate point of the heat exchanger between the two ends and for sending to the booster, means (CL1, 21) for sending compressed air from the booster to the heat exchanger, means for sending cooled air (9, 11) in the heat exchanger to the turbine, means (17, 13) for sending air expanded in the turbine to the column system, means for withdrawing from the column system a flow enriched in oxygen (31) and a flow enriched in nitrogen (33), these means being connected to the heat exchanger characterized in that '' it comprises means (V3) for relieving the compressed air in the booster, in that it does not include any cooling means between the discharge of the booster and the means for relaxing the boosted air and in that it comprises means for sending air, boosted in the booster and expanded by the expansion means, upstream or downstream of the turbine, without having been cooled in the heat exchanger after having been boosted. 2. Apparatus according to claim 1 comprising means for detecting the pressure drop or the flow between two points of the booster (C2) as well as means for opening the expansion means (V3) to send the boosted air upstream or in downstream of the turbine without passing through the heat exchanger depending on the pressure drop or the flow rate of the booster. 3. Apparatus according to claim 1 or 2 wherein the booster (C2) is connected to the inlet of the turbine (T2) so that the boosted air can relax at least partially in the turbine. 4. Method of air separation by cryogenic distillation in which all the air to be distilled is compressed in an air compressor, at least part of the air to be distilled is compressed, compressed in the air compressor in a booster compressed air (C2), in at least one expansion turbine (T2, T1), compressed air from the compressor and possibly from the air blower is separated, separated from the compressed air cooled in a heat exchanger (E) in a cryogenic distillation column system comprising at least one column (K1, K2), cooled air is taken from an intermediate point of the heat exchanger between its two ends to send to the booster, it is sent compressed air from the supercharger to the heat exchanger, we send cooled air in the heat exchanger to the turbine, we send expanded air in the turbine to the column system, we extract from the system columns a flow enriched in oxygen (31) and a flow enriched in nitrogen (33) and these flows are reheated in the heat exchanger, characterized in that if the pressure drop between two points of the booster passes below a threshold and / or a flow rate of the booster passes below a minimum flow rate of the booster, part of the compressed air is relaxed in the booster without having cooled it between the booster and the expansion valve and the expanded compressed air is sent upstream or downstream of the at least one turbine, without having been cooled in the heat exchanger after having been boosted. 5. Method according to claim 4 wherein if, preferably only if, the pressure drop between the two points is above the threshold and / or a flow rate of the booster (C2) is above the minimum flow rate of the booster, we send all the air from the booster to the heat exchanger (E) to cool 6. The method of claim 4 wherein that if the pressure drop between the two points of the booster passes below the threshold and / or a flow rate of the booster passes below the minimum flow rate of the booster, no part of the compressed air upstream of the booster. 7. The method of claim 4 or 5 wherein the compressed and expanded air is expanded in the turbine (T2) if the pressure drop between the two points of the booster (C2) falls below the threshold (and / or a flow rate of the booster passes below the minimum flow rate of the booster and preferably no air flow from the booster is expanded in the turbine if the pressure drop between the two points of the booster is above the threshold and / or a flow of the booster passes above the minimum flow. 8. The method of claim 4 or 5 wherein if the pressure drop between the two points of the booster (C2) falls below the threshold (and / or a flow rate of the booster passes below the minimum flow rate), the compressed air is expanded to the pressure of a column (K1, K2) of the column system, is mixed with the air from the turbine (T2) and is sent to the column. 9. The method of claim 4, 5, 6 or 7 in which if the pressure drop between the two points of the booster is above the threshold (above the minimum flow rate, all the supercharged air is sent to cool in the heat exchanger (E). 10. Method according to one of claims 4 to 8 wherein the expanded compressed air sent to the turbine (T2) is sent to a turbine coupled to the booster from which the air comes. 11. Method according to one of claims 4 to 8 wherein the boosted compressed air sent to the turbine is sent to a turbine (T2) receiving air, or all the air it expands, from the booster ( C2). 12. Method according to one of claims 4 to 9 wherein the turbine (T2) receives air from the booster only in the case where the pressure drop between the two points of the booster is below the threshold.