EP3057680A1

EP3057680A1 - Polymerisation system having a regeneration device for an adsorptive and/or catalytic cleaning device, regeneration device, and regeneration method

Info

Publication number: EP3057680A1
Application number: EP14786127.2A
Authority: EP
Inventors: Volker Witzleb; Markus Dietzen; Uwe Göbel; Andre Heller; Olivier Grosse
Original assignee: Linde GmbH
Current assignee: Linde GmbH
Priority date: 2013-10-15
Filing date: 2014-10-02
Publication date: 2016-08-24
Also published as: JP2017500378A; EA201690758A1; CN105828911A; WO2015055284A1; BR112016007543A2; PH12016500669A1; KR20160070184A; DE102013017123A1; AU2014336604A1; US20160236173A1; CA2926213A1

Abstract

The invention relates to a polymerisation system (100) for obtaining at least one polymerisation product (1) from at least one gaseous, hydrocarbon-rich feed stream (1, 2), which system comprises at least one catalytic and/or adsorptive cleaning device (20) for the at least partial extraction of at least one undesirable component in the at least one feed stream (1, 2) and a regeneration device (10) for the regeneration of the cleaning device (20). The regeneration device (10) is designed to at least intermittently condition and conduct a regeneration gas stream (4) through the cleaning device (20) by means of a partially closed gas circuit (11). The invention further relates to a corresponding regeneration method.

Description

description

Polymerization plant with re eneriereinrichtung for adsorptive and / or catalytic cleaning device, regenerator and Regenerierverfahren

The present invention relates to a polymerization plant for obtaining at least one polymerization product using at least one gaseous, hydrocarbon-rich feed stream and a regeneration unit and a regeneration process according to the preambles of the independent

Claims. State of the art

In the production of polymerization products from gaseous,

hydrocarbon-rich feed streams, these are often not directly to

Polymerization used but previously cleaned. This is described below using the example of the production of ethylene-propylene elastomers, but also applies to a variety of other systems.

Ethylene-propylene elastomers are described, for example, in the article "Rubber, 3rd Synthetic" in Ullmann's Encyclopedia of Industrial Chemistry, online publication June 15, 2000, DOI 10.1002 / 14356007.a23_239.pub4. It is a family of random copolymers with fully saturated polymer backbone, which is why the abbreviation M is used according to DIN / ISO 1629. A distinction is made between ethylene-propylene copolymers (EPM) and terpolymers (EPDM). The monomers used for the production of EPM and EPDM ethylene and

Propylene is typically used at greater than 99% purity and must be substantially free of impurities such as hydrogen, oxygen, water, carbon monoxide, carbon dioxide, ammonia, methanol, acetylene, methyl acetylene, carbon disulfide, carbonyl sulfide, sulfur, arsenic and hydrogen sulfide, and mercaptans. Nitriles, oxygenates and phosphines. The residual contents of such compounds must not exceed certain minimum amounts, since they partially catalyst poisons for the Ziegler used in the polymerization, for example. Natta or metallocene catalysts or may affect the polymerization otherwise.

However, if the monomers ethylene and propylene originate from conventional sources, for example steam crackers, which are operated with naphtha as an insert, these still contain considerable amounts of corresponding impurities. For their removal, therefore, cleaning devices are used in which several cleaning stages can be connected in series. Such purification stages are in each case containers which contain a catalytically and / or adsorptive cleaning medium, if appropriate on appropriate supports, and through which ethylene and propylene are typically conducted as separate gas streams.

For example, in an ethylene stream in a first step

Hydrogen, oxygen, carbon monoxide and acetylene are reacted to metal oxide. In one or more further steps, water, carbon dioxide, ammonia and oxygenates may each be suitably modified

Alumina adsorptively removed.

From a propylene stream, in a first adsorption step on suitably modified alumina, carbon dioxide, carbon disulfide, carbonyl sulfide and hydrogen sulfide can be removed by adsorption. In another

Adsorption step on suitably modified alumina can be water,

Ammonia, oxygenates, mercaptans and nitriles are removed. Arsenic and phosphines can subsequently be reacted on metal oxide catalysts. In further adsorption steps on suitably modified alumina, carbon monoxide and carbon dioxide are then removed.

It is understood that the steps mentioned can also be used in a different order and, depending on the impurities contained, in a different combination or only partially.

The said catalytic and / or adsorptive cleaning devices must be regenerated after exhaustion of their capacity. This is done at least in part by means of a Regeneriergasstroms, which is passed through said container and is free of the components to be removed in each case. The regeneration gas flow is typically suitably conditioned, ie heated, cooled, brought to a certain pressure and / or charged with additional gas streams.

In particular, pure nitrogen is used as the regeneration gas stream, to which other components may also be mixed. The provision of correspondingly large amounts of pure nitrogen is complicated and expensive.

The invention seeks to remedy this situation and make the regeneration of catalytic and / or adsorptive purification devices in polymerization easier and cheaper.

Disclosure of the invention

Against this background, the invention proposes a polymerization plant for obtaining at least one polymerization product from at least one gaseous, hydrocarbon-rich feed stream having at least one

catalytic and / or adsorptive cleaning device for the at least partial removal of at least one undesired component in the at least one feed stream and with a regeneration device for the regeneration of

Cleaning device, a corresponding regenerating device and a corresponding Regenerierverfahren with the features of the independent

Claims. Preferred embodiments are subject of the dependent claims and the following description. Before explaining the advantages obtainable in the context of the present invention, some of the terms used are explained.

A "polymerization plant" is understood here to mean a plant which is set up to synthesize a polymer from monomers, in particular a plant to which the respective monomers are fed as gaseous, hydrocarbon-rich streams. In particular, this may be a polymerization plant for the production of ethylene-propylene elastomers such as EPM and EPDM, wherein ethylene and propylene are used as monomers. These monomers are fed to the polymerization plant in the form of separate gas streams and cleaned individually. However, it may also be provided in other polymerization plants be to combine several gaseous, hydrocarbon-rich feed streams together and clean together.

A "polymerization product" is any product of such a plant obtained from corresponding monomers by polymerization. These may in particular be copolymers or terpolymers, in particular EPM and EPDM.

The "catalytic and / or adsorptive cleaning device" comprises one or more containers that have a catalytic and / or adsorptive working

Cleaning medium, optionally on appropriate carriers included. This also includes cleaning media for the so-called chemisorption. Corresponding containers are hereinafter referred to as "cleaning container". The gaseous, hydrocarbon-rich feed streams are through this

Cleaning container guided while cleaning. A corresponding feed stream can also be passed in succession through a plurality of corresponding cleaning containers, it is also possible to clean a feed stream in parallel in several cleaning containers. As explained above, for the purification of ethylene and propylene for

Preparation of ethylene-propylene elastomers typically several

Cleaning stages (and thus cleaning tank) serially arranged one behind the other.

A "regenerator" is adapted to regenerate the purifier by directing one or more gaseous streams through one or more purge vessels filled with the adsorptive and / or catalytic purification medium. A corresponding regeneration device can be provided for directing a gas flow, which is referred to here as "regeneration gas flow", either only through one or in succession or in parallel through a plurality of cleaning vessels of a corresponding purification device. Is a regenerator capacitively designed to simultaneously several

Cleaning tank parallel to each other with a Regeneriergasstrom too

this will speed up the regeneration process. In particular, in cases where regeneration is rarely required, it is favorable, however

Regeneriereinrichtung be dimensioned so that in each case only a cleaning tank or only a part of the cleaning tank is acted upon by the Regeneriergasstrom. This makes it possible to design the regeneration device, which is anyway only required at times, to be smaller and less expensive. The "conditioning" of the Regeneriergasstroms in the present case includes any adjustment of its chemical and / or physical properties. In particular, the conditioning comprises heating, cooling, setting a predetermined pressure, feeding in further components, purifying the regeneration gas stream itself, and / or setting a predetermined one

Flow rate.

A "partially closed gas cycle" is a gas cycle in which the majority of the gas contained in a regular operation is performed cyclically. However, a partially closed gas cycle may also include means for feeding or extracting gas streams, for example for

Discharging unwanted components and / or conditioning a Regeneriergasstroms, which is guided in the gas cycle. However, at least 75%, if appropriate also at least 80%, 90%, 95% or 99% of the gas present in the gas cycle, for example a regeneration gas stream, always remain, so that only a correspondingly small proportion of at most 25%, if appropriate also at most 20%, 10%, 5% or 1% by removal or

Infeed of fresh gas is replaced. It is understood, however, that at

Commissioning of a corresponding gas cycle this initially filled with a corresponding gas and possibly also can be rinsed several times with gas.

ADVANTAGES OF THE INVENTION The present invention is based on a known polymerization plant for obtaining at least one polymerization product from at least one gaseous, hydrocarbon-rich feed stream. Such

Polymerization plant has at least one catalytic and / or adsorptive

Cleaning device for at least partially removing at least one undesirable component in the at least one feed stream and comprises a regeneration device for the regeneration of the cleaning device. The features of a polymerisation system constructed from corresponding components have already been explained above. According to the invention, the regeneration device is at least temporary

Conditioning and at least temporarily guiding a Regeneriergasstroms established by the cleaning device by means of a partially closed gas circulation. As explained, at least 75% or more of the gas present in the gas cycle, in this case the regeneration gas stream, always remains in such a partially closed gas cycle at each cyclical pass. This is advantageous because it causes considerable amounts of regeneration gas,

especially pure nitrogen, save. For example, in a polymerization plant for the production of EPDM, up to 12 tons of ethylene per hour and up to 8.6 tons of propylene are cleaned per hour. The regeneration of adsorptive and / or catalytic purification equipment used for this purpose requires nitrogen in conventional plants to the value of up to 500,000 euros per year, assuming a standard retail price of pure nitrogen of 120 euros per ton basis. Even if lower nitrogen prices are used, for example 60 euros per tonne, the required pure nitrogen is a considerable cost factor. In conventional systems, the nitrogen used in this case is blown off after flowing through the cleaning device into the environment. To reduce this amount, a method is known from EP 2 421 902 A1, which makes it possible to reduce the total nitrogen consumption by about 35% and the maximum volume flow by about 16%. By using the partially closed gas cycle of the present invention, however, a further significantly improved reduction can be achieved. This results in significant savings in operating costs

corresponding installations, in particular installations for the provision of

Pure nitrogen or other suitable regeneration gases. Corresponding plants or the conversion of existing plants lead only to small additional

Investment costs, for example, because a corresponding supply system for pure nitrogen can be designed for lower power due to the lower total and peak demand.

By means of the method proposed by the invention is the

Total nitrogen consumption reduced by up to 70%. The implementation costs for the provision of inventively designed regenerating device are typically amortized in less than 2 years.

Due to the specific design of the regeneration device, the polymerization system according to the invention allows a multiplicity of conditioning options for a corresponding regeneration gas flow. For this purpose, at least one heating device, at least one cooling device and / or at least one compressor is advantageously provided in the gas circulation of the regenerating device. The

Regenerator can thus flexibly operate different modes of operation in the regeneration, for example, for drying, oxidation, reduction and further steps in the regeneration in the cleaning tanks. All such steps are summarized under the generic term "regeneration".

For a plurality of cleaning containers of a cleaning device can be provided a common regenerating device and as common

Regenerating system can be used for different types of adsorptive and / or catalytic cleaning media.

In other words, different adsorbers and / or catalytic

Purification reactors (which can also work by means of so-called chemisorption) are acted upon by the Regeneriergasstrom. The regeneration gas in the illustrated circuit can be heated, cooled and diluted with air, for example. It can also be continuously fed a limited amount of fresh nitrogen in the circulation. The discharge of a certain amount of the regeneration gas from the at least partially closed gas circulation can be pressure-controlled, whereby in particular a predetermined (back) pressure in the gas cycle can be maintained.

As explained, the gas circulation may therefore have at least one feed device and / or at least one removal device for a gas flow. For certain regeneration tasks, for example, a certain

Oxygen content in the regeneration gas may be required. For this purpose, it may be provided to feed oxygen and / or air into the gas cycle. Specifically, the feed amount may be adjusted using a controller that operates based on a measured amount of oxygen in the gas loop. Exceeds the amount of oxygen required for regeneration one

given value, may be provided for safety reasons an additional connection for instrument air. As also partially explained, the cleaning device may comprise a plurality of each filled with a cleaning medium cleaning container and the

Regenerating device for alternative, successive or simultaneous guidance of Regeneriergasstroms be set up by at least two cleaning containers. As explained above, it is advantageous, in particular in the case of regeneration which is not always required, and / or in the case of little expenditure of time, for a corresponding regeneration, if the cleaning device is capacitive only for the simultaneous regeneration of a

Cleaning container is set up. This is smaller and can therefore be created significantly cheaper. In particular, the regenerating device is also adapted to the

Regenerating gas stream temporarily not to lead through the cleaning device.

During such times, the cleaning unit can be bypassed, for example with a bypass line. These are periods in which the cleaning device operates catalytically and / or adsorptively and is not regenerated. An inventively designed regenerating device can also be shut down during such periods.

As explained, the present invention is particularly suitable for use in polymerization plants, which are designed to obtain at least one ethylene-propylene elastomer of ethylene and propylene.

In this case, the purification device is advantageously for the at least partial removal of hydrogen, oxygen, water, carbon monoxide, carbon dioxide, ammonia, methanol, acetylene, methyl acetylene, carbon disulfide, carbonyl sulfide, sulfur, arsenic, hydrogen sulfide, mercaptans, nitriles, oxygenates and / or phosphines from the at least a gaseous,

hydrocarbon-rich feed stream established. As explained, the regeneration device can be adapted particularly flexibly to the respective components to be removed and / or the cleaning media used for this purpose. The cleaning device may advantageously comprise at least one modified alumina and / or at least one metal oxide catalyst. Further absorptive and / or catalytic cleaning agents can be provided and regenerated in each known manner.

For the features and advantages of the regenerating device according to the invention, reference is expressly made to the above explanations. Such

Regenerating device, in particular for a polymerization plant for obtaining at least one polymerization product as explained above, is characterized

According to the invention, that it is designed for at least temporarily conditioning and guiding a Regeneriergasstroms by a catalytic and / or adsorptive cleaning means by means of a partially closed gas cycle, as explained above.

A process for regenerating a catalytic and / or adsorptive

Cleaning device of a polymerization plant for obtaining at least one polymerization product from at least one gaseous,

hydrocarbon-rich feed stream is also the subject of the invention. In this case, the cleaning device is set up to at least partially remove at least one undesired component in the at least one feed stream. The method according to the invention comprises using a regeneration device, by means of which at least temporarily a regeneration gas stream is conditioned and guided through the cleaning device by means of a partially closed gas circulation of the regeneration device. The features of the process according to the invention have already been explained above with reference to the polymerization plant provided according to the invention. In particular, it is envisaged to carry out the process according to the invention in a previously explained polymerization plant. This advantageously comprises at least two different operating modes in which the regeneration gas flow can be conditioned differently and thus adapted to the respective regeneration tasks.

The invention will be explained in more detail below with reference to the accompanying drawings which show preferred embodiments of the invention. Brief description of the drawings

Figure 1 shows a polymerization plant according to an embodiment of the invention in a schematic representation.

Detailed description of the drawings

1 shows a polymerization system according to an embodiment of the invention is shown schematically and designated 100 in total. The polymerization unit 00 is shown very schematically. In particular, has been dispensed with the representation of a variety of valves and control and regulating devices.

The polymerization system 100 in the example shown two

hydrocarbon-rich feed streams 1 and 2 fed, which may be, for example, ethylene and / or propylene.

The polymerization plant 100 comprises a purification device 20 and a regeneration device 10 and a polymerization unit 30, which is shown only schematically. In this, a polymerization product 3 is obtained. In normal operation of a corresponding polymerization plant 100, the

hydrocarbon-rich feed streams 1, 2 passed through cleaning tank 21 to 25 of the cleaning device 20 and in the polymerization device 30th

polymerized.

In normal operation of a corresponding polymerization plant 100

For example, the feed stream 1 first passed through the cleaning tank 21 and then through the cleaning tank 22. The feed stream 2, however, is first passed through the cleaning tank 23, then through the cleaning tank 24 and finally through the cleaning tank 25.

However, FIG. 1 shows a regeneration operation for the cleaning device 20. This means that in the time shown, the hydrocarbon-rich

Feed streams 1, 2 are not passed through the cleaning device 20, as illustrated by dotted arrows. The cleaning device 20 is doing regenerated, wherein a Regeneriergasstrom 4 is performed in the illustrated example by the cleaning device 21. The other cleaning containers 22 to 25 are not currently being regenerated, as illustrated by dashed arrows. The regenerating device 10 is in the example shown for successive

Regenerating the cleaning containers 21 to 25 formed, so that a

Regeneriergasstrom 4 is successively passed through the cleaning tank 21 to 25. As explained, however, several of the cleaning containers 21 to 25 can be cleaned in parallel. The regenerating device 10 includes a partially closed gas circuit 1 1. As explained, a corresponding gas circuit 11 is then partially closed, if at each pass only at most 25% of the contained gas, here the Regeneriergasstroms 4, are replaced. A Regeneriergasstrom 4 in the gas circuit 1 1 can be conditioned in the regenerating device 10 in different ways, for example, heated by a heater 12, by means of a cooling device 13, which illustrated with an only hinted

Cooling water circuit can be operated, cooled, and compacted by means of a compressor M coupled to a compressor 14. Via feed devices 15 gas streams can be fed, which may be, for example, nitrogen, air and / or other gas components.

Furthermore, two removal devices 16 are provided in the illustrated example, which are provided with corresponding valves. At the removal devices 16, a part of the guided in the gas circuit 1 1 Regeneriergasstroms 4 can be discharged. By an appropriate adjustment of the valves in the

Removal devices 16, a suitable back pressure in the gas circuit 1 1 are set so that the Regeneriergasstrom 4 is always ready with a predetermined pressure. The regeneration device or its gas circuit 11 may have a plurality of bypass lines, here by way of the example of the bypass lines 17 and 18

illustrated include. For example, the compressor 14 and / or the cleaning device 20 (if no regeneration gas stream 4 in the

Cleaning device 10 is required) are bypassed.

At different points in the gas circuit 11 measuring and / or

Control means 19 may be provided, which are illustrated here very schematically. For example, an oxygen content of Regeneriergasstroms 4 in the gas circuit 11 and / or a pressure can be measured by means of appropriate measuring and adjusted on this basis a feed of air and / or oxygen and / or a valve position in the removal devices 16.

Claims

claims

Polymerization plant (100) for obtaining at least one

Polymerization product (3) from at least one gaseous,

hydrocarbon-rich feed stream (1, 2), with at least one catalytic and / or adsorptive cleaning device (20) for at least partially removing at least one undesired component in the at least one feed stream (1, 2), and with a regeneration device (10) for

Regeneration of the cleaning device (20), characterized in that the regeneration device (10) for at least temporarily conditioning and guiding a Regeneriergasstroms (4) by the cleaning device (20) by means of a partially closed gas circulation (11) is established.

Polymerization plant (100) according to claim 1, wherein in the gas circulation (11) at least one heating device (12), at least one cooling device (13) and / or at least one compressor (14) are arranged.

Polymerization plant (100) according to claim 1 or 2, wherein the gas circulation (1 1) at least one feed device (15) and / or at least one

Removal device (16) for a gas flow.

Polymerization plant (100) according to one of the preceding claims, wherein the cleaning device (20) comprises a plurality of each with a cleaning medium (26) filled cleaning container (21 - 25) and the regeneration means (10) for alternately or simultaneously guiding the Regeneriergasstroms (4) at least two cleaning containers (21-25) is set up.

Polymerization plant (100) according to one of the preceding claims, wherein the regeneration device (10) is set up for operation in different operating phases, in which the regeneration gas flow (4) by means of

Regenerating device (10) is conditioned differently.

Polymerization plant (100) according to one of the preceding claims, wherein the regeneration device (10) is adapted for temporarily not passing the regeneration gas stream (4) through the purification device (20).

A polymerization plant (100) according to any one of the preceding claims, adapted to recover at least one ethylene-propylene elastomer from ethylene (1) and propylene (2).

8. Polymerization plant (100) according to one of the preceding claims, wherein the purification device (20) for the at least partial removal of hydrogen, oxygen, water, carbon monoxide, carbon dioxide, ammonia, methanol,

Acetylene, methyl acetylene, carbon disulfide, carbonyl sulfide, sulfur,

Arsine, hydrogen sulfide, mercaptans, nitriles, oxygenates and / or phosphines from the at least one gaseous,

hydrocarbon-rich feed stream (1, 2) is set up.

9. polymerization plant (100) according to any one of the preceding claims, wherein the cleaning device (20) comprises at least one modified alumina and / or at least one metal oxide catalyst.

10. regeneration device (10), in particular for a polymerization plant (100) according to any one of the preceding claims, characterized by means for at least temporarily conditioning and guiding a Regeneriergasstroms (4) by a catalytic and / or adsorptive cleaning means (20) in the form of a partially closed Gas cycle (11).

11. A process for regenerating a catalytic and / or adsorptive

A cleaning device (20) of a polymerization plant (100) for obtaining at least one polymerization product (1) from at least one gaseous, hydrocarbon-rich feed stream (1, 2) arranged to at least partially remove at least one undesired component in the at least one feed stream (1, 2) characterized in that a regeneration device (10) is used, by means of which at least temporarily a Regeneriergasstrom (4) conditioned and in the form of a partially closed gas circulation (11) through the cleaning device (20) is guided.

12. The method according to claim 11, which in a polymerization plant (100) according to

one of claims 1 to 9 is performed.

13. The method of claim 11 or 12, which is carried out in at least two different operating modes in which the Regeneriergasstrom (4) is conditioned differently.