Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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Background of the Invention ~ ~
This invention relates to a process for preparing hydroperoxides from : ~-
polyalkylbenzenes in the presence of sulfolane.
The use of sulfolane to increase the rate of formation of hydroperox- ;~
ides from alkyl- and polyalkylbenzenes is disclosed in U.S. Patent No. 3,524,888This patent also discloses that when an alkylbenzene like toluene, ethylbenzene,cumene or a polyalkylbenzene like ortho-xylene, 1,3,5-trimethylbenzene or 4-
isopropyl-o-xylene are oxidized in the presence of sulfolane a homogeneous
solution is formed. The homogeneous solution enables better contact of the re- -;
actants and aids in the reaction and permits ready separation of the hydroper-
oxide products. When 5-isopropyl-m-xylene (3~5-dimethylcumene) was oxidized in
the presence of sulfolane there was no apparent increase in the rate of forma-
tion of hydroperoxides. The lack of such an increase occurred because of the
immiscibility of 5-isopropyl-m-xylene in sulfolane preventing the formation of
a homogeneous reaction mixture.
It is well known to produce resorcinol or hydroquinone from meta-di-
~sopropylbenzene or para-diisopropylbenzene, respectively, by oxidation ~o pro-
duce the dihydroperoxide which by cleavage with strong acid catalysts is con-
verted to resorcinol or hydroqllinone and acetone. The oxidation of both alkyl
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f groups of the meta-, or para-diisopropylbenzene (DIPB) is readjly inhibited and
only par~ial oxidation can be achieved without considerable loss of efficiency
and rate of oxidation. DIPB is oxidized first to the mono-hydroperoxide which
is then further oxidized to the dihydroperoxide. In actual practice the re-
action is stopped at a high mono-/dihydroperoxide ratio to reduce the formation
of the numerous undesirable by-products otherwise formed in the oxidation of
DIPB, such as carbinols, ketones, and carbinol-hydroperoxides which interfere
with the oxidation. Increasing the temperature will increase the rate of re-
action but it will also increase the formation of by products. Therefore, a
balanced operation requires relatively moderate temperatures of around 80-90 C.
Even at these conditions with a low rate of reaction the reaction eventually
stops due to the inhibition of the oxidation by-products9 and the ratio of
DIPB-mono-/-dihydroperoxide is high.
It would be most desirable to increase the rate of reaction to hydro
peroxides and to increase the conversion to DIPB-dihydroperoxide by oxidizing
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the DIPB in the presence of sulfolane. Unfortunately, the ~IPB, as well as
S-isopropyl-m-xylene, and other polyalkylbenzenes, which have at least one
alkyl group having three or more carbon atoms where one carbon atom is a terti-
ary carbon atom, including compounds such as 1,3,5-triisopropylbenzene, is
immiscible with sulfolane. This immiscibility prevents the formation of a
homogeneous reaction mixture and, therefore, also prevents the benefit of higherreaction rates in the production of hydroperoxides from the above-mentioned
compounds.
It is an object of this invention to provide a process to enable the
2~ formation of a homogeneous reaction mixture when polyalkylbenzenes that are
im~iscible in sulfolane are oxidized in the presence of sulfolane to obtain an
increased rate of reaction in the formation of hydroperoxicles.
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Su~mary o.f the Invention
This .invention provides in a process for the hydroperoxidation of
polyalkylbenzenes of the formula:
Rl ~,t ( R2 '
wherein Rl is an alkyl group having three to six carbon atoms, one of which
is a tertiary carbon; and R2 is an alkyl group having one -to six carbon
atoms and x is an integer from 1 to 3 and that have a poor solubility in
sulfolane, which comprises contacting said polyalkylbenzene in the liquid
phase with oxygen or an oxygen-containing gas mixture at a temperature of
75 to 150 C in the presence of sulfolane in an amount of 25 to 150 percent
10 by weight based on the amount of said polyalkylbenzene, the improvement
comprising:
(a) contacting said polyalkylbenzene ~in the liquid phas~ with
` oxygen to oxidize the polyalkylbenzene at least by about10 percent based on tha amount of polyaIkylbenzene before
the addition fo the 25 to 150 percent by weight of sulfo-
lane and the continuation of the oxidation in order to
effect a homogeneous solution of said polyalkylbenzene
and sulfolane at reaction conditions.
Detailed Description of the Invention
. Polyalkylbenzenes which are preoxidized by the process of this
; invention are those that are immiscible with sulfolane, Eor example, meta-
diisopropylbenzene, para-diisopropylbenzene, S-isopropyl-m-xylene, tri-
isopropylbenzene and diisopropyl toluene~ The polyalkylbenzenes become
miscible with sulfolane after being treatedbY the peroxida-tion step of the
present invention. The homogeneous solution, wherein sulfolane is the
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solvent, and which is formed as a result of this miscibility, proyides many
benefits~ These benefits are i.ll~strated in U.S. Patent No. 3,524,888.
The predominant benefi-t is that the rate of formation of hydropero~ides ~om
the polyalkylated aromatic hydrocarbon is increased. General:Ly, the pro-
cess of the present invention does not vary depencling on what polyalkylbenzene
is used, but ~Iy minor variations are within the ability of one skilled in
the art.
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In the preferred embodiment of the present invention meta-diisopro-
pylbenzene (m-DIPB) is used as the polyalkylbenzene since its dihydroperoxide
can be cleaved by strong acid catalysts to produce resorcinol. Also, the hydro-
peroxide solution could be used for the production of a mixture of isopropyl-
phenol and dihydric phenol by the acid-cataly~ed cleavage of the mixed DIPB-
mono-/dihydroperoxide. The m-DIPB is added in the liquid state to any suitable
oxidation reactor to give good gas/liquid contact, which is capable of maintain-ing oxygen pressure at the desired level and which may be equipped with an
agitation device. Gaseous oxygen or an oxygen containing gas, such as air, or
oxygen in admixture with a non-reactive gas, such as nitrogen, is normally
added near the bottom of the reactor to improve the contact between the oxy~en
and the liquid m-DIPB. The rate of oxygen flow can be varied over a wide range
and such rates are known to those skilled in the art. The reaction is in the
liquid phase at temperatures between 7~-150C. Atmospheric pressure is prefer-
1~ able although superatmospheric pressures may be used. The reaction time is
I suFficient to allow at least about 10 percent and preferably 15 to 25 percent
¦oxidation of the m-DIPB. Although any percent of oxidation of m-DIPB above
¦about 10 percent may be used, a practical limit above which the invention is
Iless beneFicial and less economic is around 55 percent oxidation of m-DIPB.
¦The higher amounts, around 55 percent, of oxidation of m-DIPB are useful when
I ¦the m-DIPB contains impurities.
¦ As ln conventional hydroperoxide producing processes, the reaction is
¦performed in the presence of small amounts of basic metal salts, oxides, or
¦hydroxides. The amounts used should be that which is sufficient to neutralize
¦acidic compounds formed during the reaction. The carbonates, hydroxides, and
¦acetates of the alkali metals, and oxides or hydroxides of alkaline earth metals
¦are preferred. Examples include magnesium oxide, sodium carbonate, sodium
¦acetate and the like. In addition to basic metal salts, oxides, or hydroxides,
!a catalytic a~ount of an initiator such as diisopropylbenzene monohydroperoxide3~ ~is added to the reaction.
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lU99747
After the desired level of oxidation has been achieved the sulfolane
is added to the reaction mixture. The amount of sulfolane added is between 25
to 150 percent based on the weight of m-DIPB. Lesser amounts do not give the
four-fold or more increase in the rate of hydroperoxide Formations while the
use of more than about 150 percent does not provide any additional benefits and
; would be uneconomical. After the addition of the sulfolane the reaction mix-
ture is a homogeneous mixture. The oxidation of this homogeneous mixture is con
tinued at the same conditions of temperature and pressure as the pre-oxidation
until optimum oxidation is achieved.
The amount of oxidation may be measured by periodic sampling of the
reaction mixture and determining the amount of oxidized products of m-DIPB
present in the reaction mixture. This determination may be performed by any
method known to those skilled in the art.
The homo~eneous solution of hydroperoxides in sulfolane also permits
ready separation of the hydroperoxide. The addition of water to the homogeneous
reaction mixture after the oxidation causes a phase separation. By this ph~se
separation the bulk of the hydroperoxide is carried by tlle solvent into the
water phase. Then merely by decantation or the like~ the phases can be sepa-
rated and the hydroperoxides concentrated or decomposed to useful produ~ts by
conventional means. For example, the separated hydroyeroxides can be decomposed
y acid catalysis to make mono- and/or dihydric phenols and acetone. In addi-
tion the acid-catalyzed decomposition can be performed on the water-separated
sulfolane phase rather than directly on the hydroperoxides.
The process can be operated as a batch process or can be carried out
'~ as a continuous operation. The oxidation reaction zones may consist of one orore than one vessel. One vessel may be used for the preoxidation reaction zone
nd another vessel may be used for the oxidation reaction zone. In the case of
continuous operation, the effluent from preoxidation may be cascaded from the
preoxidation vessel to the oxidation vessel to which the sulfolane is added.
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In order to better illustrate the operation of the process of the
present invention the following examples are provided. These examples are for
illustrat;ve purposes and do not limit the broader process as previously
described.
Example 1
A stirred mixture of 100 grams of para-diisopropylbenzene (p-DIPB),
2.0 grams of sodium acetate and 1.0 grams of diisopropylbenzene (mono) hydro-
peroxide was aerated at 125C. for 3.5 hours at which point the level o~ oxida-
tion was 26.5 percent based on the hydroperoxide content calculated as mono-
hydroperoxide. To this mixture 100 grams of sulfolane was added and the solu-
tion was further oxidized for 3.5 hours at 125C. After this oxidation the
total hydroperoxide content (based on the p-DIPB charged and calculated as DIPB-; monohydroperoxide) was 74 wt. percent~ The hydroperoxide product was analyzed
by nuclear magnetic resonance (NMR) spectroscopy and it was ~ound that 65 per-
cent of the p-DIPB was oxidized and the mole ratio of p-DIpB-mono-hydroperoxide
-dihydroperoxide was 2.4.
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Example 2
A stirred mixture of 100 grams of meta-diisopropylbenzene (m-DIPB~,
2.0 grams of sodium acetate and 1.0 gram of diisopropylbenzene monohydro-
peroxide was aerated at 125C. for 3.0 hours. At this point the level of oxi-
dation was 19.4 percent based on the weight percent of hydroperoxide tcalcu-
lated as monohydroperoxide). To this mixture 100 grams of sulfolane was added
and the oxidation was continued for 7.0 hours at 125C. The total hydroperoxide
content based on the m-DIPB charged and calculated as DlPB-monohydroperoxide
was 96 weight percent. The hydroperoxide product was analyzed by NMR spectros-
copy and it was found that 80 percent of the m-DIPB was oxidized and the mole
ratio of m-DIPB-mono-hydroperoxide/dihydroperoxide was 1Ø Also, it was found
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that only 5 percent oF the starting material had been converted to undesirable
by-products.
According to the provisions of the patent statutes the principle and
preferred mode of operation of the invention have been illustrated and de-
scribed. However, it should be understood that within the scope of the appended
. cla;ms the invention may be practiced otherwise than as specifically illustrated
: and described.