CA1189057A

CA1189057A - Catalyst mixture and process for making 1,2- dichloroethane

Info

Publication number: CA1189057A
Application number: CA000415709A
Authority: CA
Inventors: Joachim Hundeck; Harald Scholz; Hans Hennen
Original assignee: Hoechst AG
Current assignee: Hoechst AG
Priority date: 1981-12-08
Filing date: 1982-11-17
Publication date: 1985-06-18
Also published as: NO824108L; BR8207099A; AU9161582A; JPH0230298B2; AU553255B2; NO158621C; ZA828976B; SU1250165A3; NO158621B; HU193155B; IN156063B; MX162900B; EP0082342A2; DE3276154D1; CS235975B2; DE3148450A1; ES8307529A1; EP0082342A3; EP0082342B1; ES517410A0

Abstract

ABSTRACT OF THE DISCLOSURE
The disclosure relates to a catalyst mixture consisting of anhydrous iron(III)chloride and a further mixing component, for making 1,2-dichloroethane by subjecting ethylene to reac-tion with chlorine in a solvent at atomospheric or elevated pressure. The mixture is more particularly characterized in that the further mixing component is a nitrogen base or a salt thereof, which is used in a proportion approximately equivalent to the iron(III)chloride proportion.

Description

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It is known that 1,2-dichloroethane can be made by reacting ethylene with chlorine in 1,2-dichloroethane as a solvent and reaction medium. The principal by-product ob-tained in this reaction is 1,1,2-trichloroethane which ori-ginates from a substitution reaction 1,2-dichloroethane is subjected to~ In order to obviate this substitution re-action9 use is made of catalysts which comprise chlorides of the elements belonging to groups IV to VI of the Peri~-dic System, and are partially used in the presence of oxy-gen; more especially, anhydrous iron(III)chloride which isreadily accessible and inexpensive is used.
The resulting crude catalyst-containing dichloroethane is normally taken from the reaction ~essel, treated with water or aqueous alkali metal solution so as to be ~reed from catalyst and hydrogen chloride, and distillati~ely worked up in known manner.
The use of FeCl3 as a catalyst in the addition chlori-nation of ethylene entails certain adverse effects. In the presence of water, for example, FeCl3 has corrosiveness for metallic mate~ als such as those normally used for making reactors, columns or heat exchangers provided of course that these come into contact ~herewith. Needless to say, chlorine of commercial purity which is normally used for e~fecting the chlorination always contains traces of water and hy~rogen chloride origi~ating from undesirable side reactions, Whene~er it is desirable for the heat energy set free during the chlorination of ethylene to be utilized9 it is ~.

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invariably necessary for the reaction to be carried out at temperatures higher than the boiling point of dichloro-ethane at atmospheric pressure. In ~iew of the fact that corrosiveness increases considerably with increasing tem-peratures, it is indispensable to effect the chlorinationreaction in apparatus lined with corrosion-resistant mate-rials which naturally affect the commercial at-tracti~eness of the entire process.
We ha~e now ~ound that FeC13 which is used as a cata-lyst in the production of 1,2-dichloroethane is of consi-derably reduced corrosi~eness .~or reactor materials which are not corrosionproof provided that the ~eCl3-catalyst is used in admixture with certain addends. In addltion to this, the addends have been found favorably to influence by-pro-duct formation which is reduced.
The present invention relates more particularly to acatalyst mixture consisting o~ anhydrous iron(III)chloride and a further mixing component, for making 1,2-dichloro-ethane by subjecting ethylene to reaction with chlorine in a solvent at atmospheric or elevated pressure, which is cha-racterized in that the fur-ther mixing component is a n$tro-gen base or salt thereof which is used in a proportion appro-ximately equivalent to the iron(III~chloride proportion.
The nitrogen base is selected ~rom NH3, a primary, se-condary or tertiary alkyl, aralkyl, aryl or alicyclic amine or polya~ine; The salt of the nitrogen base preferably is ahalogen salt, e.g. ammonium chloride.
The in~ention also relates to a process for making 1,2-dichloroethane with the use o~ the present catalyst mixture.

5~7 The invention provides a process for makiny 1,2-dichloroethane by subjecting ethylene to reaction with chlorine in a solvent at a-tmospheric or elevated pressure in the presence of a catalyst mixture consistinc~ of anhydrous iron (III) chloride and a nitrogen base or a salt thereof, which is used in a proportion approximately equivalent to the iron(III)chloride proportion.
The process of the present invention for making 1,2-dichloroethane by subjecting ethylene to reaction with chlorine in a solvent in the presence of a catalyst mixture consisting of anhydrous iron(III)chloride and a further mixing component and, if desired, an agent inhibi-ting the formation of by-products at a temperature of about 20 to 200C, at atmospheric or elevated pressure and distil.la-tivel~ separating the 1,2-dichloroet~ane from the chlorination mixture, is more particularly characterized in that a) the further mixing component is a nitrogen hase or a salt thereof;
b) the further mïxing component is used in a propo.rtion approximately equivalent to the proportion of iron (III)chloride, and c~ the iron(III)chloride is used in a concentratio.n of O.OQ5 to about 0.5 weight ~, based on the quantity of solvent.
In describing the catalyst mixture, it has already been mentionsd that the nitrogen base should be selected from NH3~ a primary, secondary or tertiary alkyl, aralkyl, aryl or alicyclic amine or polyamine. The salt of the nitrogen base preferabl-y is a halogen salt, especially ammonium chloride.

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A preferred feature of the present process provides for 1,2-dichloroethane to be used as the solven-t and for oxygen to be used as inhibitor.
The following sta-tements are intended further to illus-trate the process of this invention.
The catalyst should generally be clissolved or suspended in the solvent placed in a reactor. It is also possible how-- 3a -ever for the catalyst to be prepared outside ~he reactor i.e. by suspending anhydrous FeC13 together with the further catalyst component in 1,2-dichloroethane, for example, and for the suspension to be introduced into the reactor St~ll further, it is possible to introduce a~hydrous FeC17 and NH3 or an amine int~ the solvent placed in the reactor, and ini-tiate a reaction during which hydrogen chloride sufficient ~or the formation o~ the corresponding ammonium salt is set free.
The present catalyst can be said to compare fa~orably with the prior art catalysts inasmuch as it is of conside-rably reduced corrosiveness for reactors made up of not cor-rosionproof metals, compared with the corrosiveness in the prior art methods for making 1,2-dichloroethane. It was also found that apart ~rom minor proportions of 1,1,2-trichloro-etha~e (as the first substitution product) and a correspon-dingly minor proportion of hydrogen chloride, practically no further by-products are being formed under the process conditions selected in accordance with this invention. The reaction solution remains~clear e~en after reaction over a prolonged period provided that the solution contains the addends of this invention in proportions approximately equi-valent to the iron chloride present. It is even possible for reaction mixture rendered dark during reaction to re-assume a lighter coloration during the Iurther course of the reac-tion, upon the addition o~ the addends specified hereinabo~e.
Further desirable results of the present process reside in the almost quantitative conversion rate at high space/time-yields.

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The process of this invention can be carried out, for e~ample, in the loop reactor described in DE-OS 24 27 045 or any other suitable reactor.
The following Examples illustrate the invention.
Example 1

2.0 kg 1,2-dichloroethane and 4 g anhydrous iron(III) chloride were placed in a loop reactor which had a capacity of about 2 liters. Next, 0.42 g ammonia which was in the form of an O.67 weight ~ solution in dichloroethane was in-troduced at 30 - 40C. The ascending portion of the reactor loop was provided with a layer of packing material. Disposed below the layer of packing material so as to open into the reactor were ethylene, chlorine and air inlets for the in-troduction of about 60 l/h each of ethylene and chlorine and 15 l/h air. The reactor liquid was circulated in the reactor system in accordance with the principle underlying a mammouth pump and the catalyst mixture was thereby homo-geneously suspended in the liquid phase. During the reaction, a temperature of about 77C was found to establish in the reaction mixture. The concentration of the catalyst mixture, determined as FeCl3, which was dissolved in the reactor li-quid, was 0,13 weight % after se~eral days. Dichloroethane in vapor form which came from the reactor was condensed in a water cooler arranged above the reactor. 3y means o~ a con-densate distributing means, a condensate portion correspond-ing to the quantity produced was ~aken from the cooler whilst condensate in excess was recycled to the reaction zone. By means of a cooling trap, a further dichloroethane p~rtio~
was separated from issuing gas which consisted substantially ~ 8 ~

of inert gases. After continuous operation over 2 period o~ several days, the catalyst mixture was found to have been extensively dissolved in the reactor liquid; the Fe-content in the reac~or liquid was determined colorimetrical-ly and f~und to be about 0.13 weight %. The experiment wasr~n o~er a period o~ 14 days and 1,2-di.chloroethane was ob-tained at an hourly rate of 262 g.
Product A which was obtained in the condenser and Pro-duct B which was reactor liquid were analyzed a~ter the re-action had been terminated, and the following results wereobtained:

Product A Product B
wgt % wgt %
_ _ ~

C2H5 l < 0.002 ~0.002 1,2-EDC 99.94 99.82 1,1,2-ETC ~.04 0.14 HCl ~ 0.001 r~r-~-r ~o-~r~ o o~ 0.04 EDC = 1,2-dichloroethane ETC = 1,1 7 2-trichloroethane Ex~mple 2 The procedure was as in Example 1 but the reaction mixture circulated through the reactor was ad~itionally ad-mixed dropwise by means of a dropptng funnel with 50 ml/h 1,2-dichl~roe~hane con~aining 0.4 weight % 1,1j2-trichloro-ethane. 1,2-dichloroethane was obtained at an hourly rate of ~26 g. The experiment was run over a period of 8 days~ Pro-duct A obtained in the condenser and reactor liquid B~ wereanalyzed after the reaction had been terminated, and the following results were obtained:
__ Product A Product B
_ wgt % wgt % .
. .. . . . _ C2H5Cl ~ 0.002 ~0.002 1,2-EDC 99.87 99.61 1,1,2-ETC 0.10 0.34 HCl ~ 0.001 Further components O.03 O.05 Example 3 The procedure was as in Example 1 but the concentration of FeCl3 in the reaction mixture and the molar ratio of FeCl3 to ammoni~ were varied. The followi~g Table indicates the va-riatio~ and its effect upon the proportions of 1,1,2-ETC and HCl in the product obtained in the condenser:

. .. . . _ . . , ., , ,,, , . , . _ Concentration Molar ratio Wgt% 1,1,2-ETC Wgt % HCl FeC1~5 (wgt%)' Fc 13 3 , ;~ .

0.07 1 : 2 0.2 0~004 0.34 1 : 2 0.6 0.002 0.45 1 : 1.5 0.1 0.001 0.32 1 : 1 0.06~ 0.001 In the experiment run with 0.32 wgt % FeC13-concen-tration over a period of 19 days, 1,2-dichloroethane was obtained at an hourly rate of 260 g. Product A obtained in the condenser and reactor liquld B were analyzed a~ter the reaction had been terminated, and the ~ollowirlg re-sults were obtained:

Pr~duct A Product B
wgt % wgt %
.. .. . . . .

C2H5Cl ' 0,002 0.002 'I,2-EDC 99.93 99.78 1,1,2-ETC 0.06 __ .0,19 HCl 0.001 Further components O.01 O.03 .. . ... . _...

Example 4 The procedure was as in Example 1 but 1.~5 kg 1,2-di-chloroethane was used and the reaction solution was admixed with 1.3 g trimethylamine dissolved in 30 ml 192-dichloro-ethane, which replaced ammon~a, The experimen~ was run over a peri~d o~ 6 days and 1,2-dichloroethane ~as obtained at an hourly rate o~ 276 g. The FeCl3-content in the solution was determined colorimetrlcally; it averaged 0.13 weight %.
Pr~duct A obtained in the condenser was analyzed after the reaction had bee~ terminated and the following results were obtained:

Product A (wgt %) 1,2-EDC 99.86 1,1,2-ETC 0.13 HCl 0.01 Fbrther ~om~e~t~ O.006 Example 5 The procedure was as in Example 4 but the catalys-t added to the reaction solution was 1.7 g FeCl3 and 0.65 g diamino-ethane. The FeCl3-content in the solution was determined colo-rimetrically; it averaged 0.07 wgt %. The experiment was run over a period of 3 days a~d dichloroethane was ~btained at an hourly rate of ~68 g, Product A obtained in ~he conde~ser was analyzed and the ~ollowing results were obtalned.

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Product A (~Ygt %j ___ _ ~

1~2-EDC 99,1 1,1,2-ETC 0.85 HCl 0,02 EIr~l~e- ~o~ =0 01 Example 6 The procedure was as in Example 1 but 1.5 kg 1,2-dichlo-roethane and 3.3 g ~eCl~ and 3.0 g triethanolamine (catalyst) were used. The FeC13-content determined colorimetrically in the reaction solution averaged 0.25 wgt ~. m e experiment was run over a period of 6 days and dichloroethane was ob-tained at an hourly rate of 268 g.
Product A obtained in the condenser was analyzed and the following results were obtained:

~-od~ t ~_ . . . , ... . _ .
C2H5Cl < 0.002 1,2-EDC 9~.65 1,1,2-ETC 0.~3 HCl 0.007 Further components O.01 , Example 7 a) 2 kg 1,2-dichloroethane and 2.1 g iron(III)chloride were placed in a 2 liter round flask provided ~ith an agita-tor, dropping ~unnel and reflux condenser, The mixture was heated ~o boiling while stirring and admixed drop-wise with 002 g ammonia which was dissol~ed in 58 g dl-5i7 chloroethane; this corresponded to a total catalyst quantity of 2.3 g. The mixture was boiled ~wnder re-flux for a further 5 hours and the FeCl3-content in the solution was determined colorimetrically; it was 0.11 wgt %.
b) The mixture of dichloroethane and catalyst was intro-duced into the loop reactor described in Example 1.
Next, about 60 l/h each o~ chlorine and ethylene were introduced together with about 5 l/h air. The experi-~ent was run over a period of 8 days ~nd dichloro-ethane was obtained at an hourly rate of 273 g.
Product A obtained in the condenser was analyzed and the following results were obtained:

Product A (Wgt ~) . , .. - . . I
C2H5Cl < 0.002 1,2-EDC 99.51 1,1,2-ETC 0.48 HCl 0.002 Further compo~ents OffOO9 Example 8 a) The procedure was as in Example 7 a) but 1.5 kg 1,2-di-chloroethane and 12 g FeCl3 were heated to boiling while stirring. Next, the mixture was admixed dropwise first with a solution of 2.7 g hydrogen chloride in 750 g di-chloroethane and then with a solution of 1.26 g ~H3 in 273 g dichloroethane~ After cooling, the reaction mix-ture was ~iltered and the filter residue dried. 14.4 g dry catalyst was obtained.

a~ 7 b) To produce 1~2-dichloroethane, 4 g of the catalyst made as described under a~ and 2 g ~eC13 were sus-pended in 2.7 kg 1,2-dichloroethane, the suspension was concentrated to a volume o~ about 2 liters and introduced into the loop reactor described in Example 1.
The loop reactor was ~ed per hour with about 60 liters each o~ chlorine and ethylene and 15 liters air and the reaction was initiated under the conditions des-cribed in Example 1. The experiment was run over a period of 6 days and 1,2-dichloroethane was obtained at an hourly rate of 266 g. The ~eCl3-content in the reaction solution determined colorimetrically averaged 0~15 wgt %.
Product A obtained in the condenser and reactor liquid B
were analyzed after the reaction had been terminated and the ~ollowing results were obtained.

Product A (Wgt %) Product B (Wgt %) ~_ C2H5 l 0.004 0.006 1,2-EDC 99.93 99.74 1,1,2-ETC 0.06 0.23 HCl 0.002 0.03 rur~her c~m~e.tsO.003 _ . _ _ Example 9 Steel specimens were tested for corrosion under the condi-tions of the process of this invention. To this end, 4 speci-mens were exposed at 4 places in a co~mercial rsactor for mak-ing 1,2-dichloroethane. The specimens were taken from the re-actor at intervals of 20 days and the material removed there-from by corrosion was determ~ned.
~ The average corrosion rate determined for unalloyed steel was less than 0.05 mm per annum in the pro-cess carried out with the FeCl3/NH3-catalyst of this in-vention at a reaction temperature maintained at 100-110C, In the prooess carried out in known marmer with the use exclusively of ~eCl3 as the catalyst, the average corro-sion rate determined for unalloyed steel was 0.43 mm per annum.

Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A process for making 1,2-dichloroethane by subjecting ethylene to reaction with chlorine in a solvent at atmospheric or elevated pressure in the presence of a catalyst mixture con-sisting of anhydrous iron(III)chloride and a nitrogen base or a salt thereof, which is used in a proportion approximately equi-valent to the iron(III)chloride proportion.

2. A process for making 1,2-dichloroethane by subjecting ethylene to reaction with chlorine in a solvent at atmospheric or elevated pressure in the presence of a catalyst mixture con-sisting of anhydrous iron(III)chloride in a concentration of 0.005 to about 0.5 weight %, based on the quantity of solvent and a nitrogen base or a salt thereof, which is used in a pro-portion approximately equivalent to the iron(III)chloride pro-portion, and, if desired, an agent inhibiting the formation of by-products at a temperature of about 20 to 200°C.

3. The process as claimed in claim 1 or 2, wherein the nitrogen base is NH3, a primary, secondary or tertiary alkyl, aralkyl, aryl or alicyclic amine or polyamine.

4. The process as claimed in claim 1 or 2, wherein the salt of the nitrogen base is a halogen salt.

5. The process as claimed in claim 1 or 2, wherein the salt of the nitrogen base is ammonium chloride.

6. The process as claimed in claim 1 or 2, wherein the solvent is 1,2-dichloroethane.

7. The process as claimed in claim 2, wherein the inhibit-ing agent is oxygen.