The invention relates to a process for ethylene recovery in a cycle gas process for preparing vinyl acetate, in which a sub-stream of the ethylenic product stream is discharged and sent to a process for recovering or converting ethylene.
Vinyl acetate is prepared in continuous processes with recycling of the purified product stream. In a heterogeneously catalysed gas phase process, ethylene reacts with acetic acid and oxygen over fixed bed catalysts which generally comprise palladium and alkali metal salts on a support material, and may additionally also be doped with gold, rhodium or cadmium.
The ethylene, oxygen and acetic acid reactants are reacted in an exothermic reaction generally at a pressure of from 8 to 12 bar and a temperature of from 130° C. to 200° C. in a fixed bed tubular reactor to give vinyl acetate:
C2H4+CH3COOH+0.5 O2=>CH3COOCH═CH2+H2O
The ethylene conversion is about 10%, the acetic acid conversion from about 20 to 30% and the oxygen conversion up to 90%.
A problem in this reaction is that inert substances are introduced via the ethylene and oxygen reactants, and are difficult to remove, but increasingly reduce the selectivity of the reaction when they are recycled into the reactor and accumulate in the cycle gas. The inerts nitrogen and argon are introduced via the oxygen, and ethane and to a slight extent methane via ethylene. These inerts have to be removed continuously from the system, otherwise their accumulation would inhibit the reaction. Since ethylene constitutes the majority of the cycle gas mixture at from 60 to 70% by volume, the removal of inerts is generally accompanied by a distinct loss of ethylene of from about 1 to 4% by volume of the amount fed. In addition, side reactions form carbon dioxide and further by-products such as methyl acetate and ethyl acetate.
Owing to the incomplete conversion of the reactants, the gaseous product stream is worked up in a continuous process: in a cycle gas scrubber operated with acetic acid, the vinyl acetate target product is washed out of the cycle gas and worked up in subsequent distillation processes. The vinyl acetate-free cycle gas is sent through a cycle gas compressor to the acetic acid saturator and subsequently to the reactor. In order to reduce the CO2 by-product, a portion of the vinyl acetate-free cycle gas is discharged on the pressure side of the cycle gas compressor and sent to a water scrubber. Subsequently, a small fraction is sent to incineration for inerts discharge, and the remainder is passed into a CO2 absorption column and then sent back to the cycle gas in CO2 free form.
The inerts discharge by means of removal of ethylene from the cycle gas prevents accumulation of ethane, methane, argon and nitrogen in the cycle gas stream. The amount of the inert stream discharged is controlled depending on the ethylene concentration in the cycle gas. When the amounts discharged are too small, the inerts become concentrated in the cycle gas and the ethylene concentration in the cycle gas falls. However, the ethylene selectivity increases with the ethylene content of the cycle gas. The higher the ethylene content in the cycle gas, i.e. the more ethylene comprising inerts from the cycle gas is removed and “fresh” ethylene is supplied, the better the ethylene selectivity is. However, from a certain proportion, a more extensive discharge of ethylene comprising inerts is uneconomic, since each additional ton of vinyl acetate monomer has to be paid for with a disproportionately high fraction of discharged ethylene comprising inerts. Since ethylene is expensive, the recovery of ethylene has the highest priority as a cost-lowering measure.
WO-A 01/00559 describes two common alternatives for ethylene recovery in vinyl acetate preparation by means of gas phase reaction of ethylene, acetic acid and oxygen.
Carbon dioxide is removed from the gas stream leaving the reactor which then comprises primarily ethylene, methane, oxygen, nitrogen and argon. At system pressure, the gas stream is passed into an absorption column and washed with vinyl acetate, and a mixture of methane, nitrogen, oxygen and argon is drawn off at the top of the column and sent to incineration. At the bottom of the column, vinyl acetate and ethylene are withdrawn, the gas mixture is decompressed and ethylene is removed from vinyl acetate. The ethylene is subsequently compressed and passed back into the reactor.
Disadvantages in this context are the energy-intensive decompression-compression step, and the fact that the inerts cannot be removed fully, and thus become increasingly enriched and distinctly lower the selectivity of the reaction.
In a further variant, to which WO-A 01/00559 is directed, the majority of the gaseous product stream is contacted at system pressure with acetic acid in an absorption vessel. At the top of the column, methane, nitrogen, oxygen and argon are removed, and a mixture of vinyl acetate, acetic acid and ethylene is drawn off at the bottom of the column. This mixture is contacted in a gas scrubber with the remaining fraction of the gaseous product stream. The ethylene is drawn off at the top and recycled into the reactor; the vinyl acetate is obtained at the bottom of the column and sent to further workup.
The decompression/compression step becomes unnecessary, but here too the inert gases accumulate increasingly in the cycle gas.
A similar process is the subject matter of U.S. Pat. No. 3,714,237, in which the gaseous stream is likewise worked up by scrubbing with acetic acid, vinyl acetate is removed, and the residual gas is recycled into the reactor after the carbon dioxide has been washed out. Here too, the inert gases accumulate increasingly in the cycle gas.
It is therefore an object of the present invention to configure the cycle gas process in the preparation of vinyl acetate in such a way that the accumulation of the inert gases mentioned is very substantially prevented.
The invention provides a process for ethylene recovery in a cycle gas process for preparing vinyl acetate by means of
In the continuous preparation of vinyl acetate, operation is effected in tubular reactors which are charged with a fixed bed catalyst. These catalysts are generally supported catalysts doped with noble metals (or noble metal salts) and promoters, for example bentonite spheres doped with palladium and with gold (cadmium) and potassium salts. The reactor is charged with ethylene, oxygen and acetic acid, and the reaction is carried out preferably at a pressure of from 8 to 12 bar and a temperature of from 130° C. to 200° C. The product gas stream leaving the reactor comprises substantially vinyl acetate, ethylene, acetic acid, water, oxygen, CO2 and the inerts nitrogen, argon, methane and ethane.
The product gas stream is subsequently separated in a cycle gas scrubber operated with acetic acid, in which vinyl acetate, acetic acid, water and further condensable fractions are removed, and the vinyl acetate monomer is obtained by means of distillative workup. After the removal of the condensable fractions (vinyl acetate, acetic acid, water), the cycle gas typically has the following composition:
This composition makes clear that, to effectively remove methane, ethane, argon and nitrogen, a relatively high proportion has to be sent to incineration, with a correspondingly high ethylene loss.
In the inventive procedure, the cycle gas is now conducted into a CO2 absorption/desorption, customarily operated with aqueous potassium carbonate solution. After the CO2 scrubbing, the cycle gas generally has the following composition:
After the CO2 scrubbing, the product stream is divided. A majority of the ethylenic cycle gas stream is recycled into the reactor via a cycle gas compressor and acetic acid saturator. The remainder of the ethylenic gas stream is discharged and reused in processes for converting ethylene. Preference is given to discharging from 1 to 25% by volume, more preferably from 5 to 20% by volume, of the ethylenic gas stream. The carbon dioxide laden with traces of hydrocarbons is passed to thermal disposal.
The recycling is effected preferably into processes for converting ethylene. Examples thereof are oxidation processes for preparing acetaldehyde and for preparing acetic acid, the oxychlorination of ethylene for preparing dichloroethane and the direct chlorination of ethylene to dichloroethane. Further examples are the preparation of ethylene oxide and ethylene glycol, alkylation of benzene to ethylbenzene and optionally de-hydrogenation to styrene, the carbonylation to acrylic acid, the polymerization to polyethylene, the hydroformylation to propionaldehyde, the Reppe carbonylation to propionic acid, and the Alfol process for preparing long-chain, primary alcohols. The ethylene may also be used for recycling in processes for refining hydrocarbons.
With the process according to the invention, the inerts discharge is no longer inevitably associated with the incineration of the valuable ethylene raw material. Virtually 100% utilization of the ethylene is possible; typically, 2% of the ethylene used is lost as a result of the inerts discharge. The generation of environmentally polluting carbon dioxide owing to ethylene incineration is prevented. This corresponds to a drop of 50 kg of CO2 per metric ton of vinyl acetate monomer.
The examples which follow serve to further illustrate the invention:
A 25 m3 tubular reactor 1 which was equipped with a Pd/Au supported catalyst was charged at a pressure of 8.5 bar and a temperature of 160° C. via line 2 with a gas mixture having a gas hourly space velocity (GHSV) of 3500 h−1. The gas mixture (cycle gas) had the following composition:
The cycle gas leaving the reactor 1 was fed via line 3 to a vinyl acetate scrubber 4 operated with acetic acid, and subsequently via line 6 to a carbon dioxide scrubber 7 operated with potash. A vinyl acetate/acetic acid/water mixture was withdrawn via line 5 from the vinyl acetate scrubber 4 and sent to further processing. After the carbon dioxide scrubbing, 200 kg/h, corresponding to approx. 7% by volume, of the cycle gas going to the CO2 removal were passed via line 8 into the acetic acid preparation for ethylene recovery, and the remainder was recycled via line 9 and the cycle gas compressor 10 into the reactor 1. The CO2 discharge for thermal disposal was effected via path 11.
Under these conditions, the catalyst exhibited a space-time yield of 650 g/l·h at an ethylene selectivity of 91.5%.
The procedure was analogous to Example 1, with the difference that, after the CO2 scrubbing, 300 kg/h, i.e. approx. 10% by volume, of the cycle gas going to the CO2 removal, have been discharged. This increased the ethylene content in the cycle gas to 64% by volume; the other components were adjusted correspondingly. The reaction conditions (GHSV, cycle gas pressure, etc.) remained the same.
The increase in the amount discharged resulted in an increase in the space-time yield to 660 g/l·h with an improvement in the ethylene selectivity to 92.5%, which corresponds to an at least 0.5% increase in the vinyl acetate production.
The procedure was analogous to Example 1, with the difference that, after the CO2 scrubbing, 450 kg/h, i.e. approx. 15% by volume, of the cycle gas going to the CO2 removal have been passed into the acetic acid preparation for ethylene recovery. This resulted in an increase in the ethylene content in the cycle gas to 66% by volume; the other components were adjusted correspondingly. The reaction conditions (GHSV, cycle gas pressure, etc.) remained the same.
The increase in the amount discharged resulted in an increase in the ethylene selectivity to 93.0%, which corresponds to a 1% increase in the vinyl acetate production.
Number | Date | Country | Kind |
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10 2004 018 284.1 | Apr 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP05/03388 | 3/31/2005 | WO | 2/19/2007 |