PROCESS FOR REGENERATING SPENT SULFURIC ACID BACKGROUND OF THE INVENTION

This application claims the benefit of provisional application 60/677,874 filed 05/05/05 . Field of the Invention

The present invention relates to a process for the regeneration of sulfuric acid containing hydrocarbons and water, such as sulfuric acid from a process wherein normal olefins are reacted with isoalkanes in the presence of sulfuric acid to produce alkylate product, to produce fresh sulfuric acid. Related Information

In the petroleum refining industry, acid catalyzed alkylation of aliphatic hydrocarbons with olefinic hydrocarbons is a well known process. Alkylation is the reaction of a paraffin, usually isoparaffins, with an olefin in the presence of a strong acid which produces paraffins of higher octane number than the starting materials and which boil in the range of gasolines. In petroleum refining the reaction is generally the reaction of a C ₂ to C ₅ olefin with isobutane.

In refining alkylations, hydrofluoric or sulfuric acid catalysts are most widely used under low temperature conditions. Low temperature or cold acid processes are favored because side reactions are minimized. In the traditional process the reaction is carried out in a reactor where the hydrocarbon reactants are dispersed into a continuous acid phase.

Although this process has not been environmentally friendly and is hazardous to operate, no other process has been as efficient and it continues to be the major method of alkylation for octane enhancement throughout the world. In view of the fact that the cold acid process will continue to be the process of choice, various proposals have been made to improve and enhance the reaction and to some extent moderate the undesirable effects.

In the alkylation process the sulfuric acid catalyst becomes diluted with hydrocarbons and water which produces a sludge which must be disposed of. Typically the sludge is burned in a high temperature combustion zone to convert the acid to sulfur dioxide and the hydrocarbons to carbon oxides and water. The sulfur

dioxide is then separated from the other combustion products and converted to sulfur trioxide in a vapor phase reaction over a vanadium-based catalyst. The sulfur trioxide is then converted to concentrated sulfuric by reaction with water in and absorber. One such process is disclosed in U.S. patent 3,907,979.

In a typical refinery or chemical application low cost spent acid disposal is not an option because of environmental regulations. Generally, the amount of spent acid produced is not sufficient to justify installation of an onsite conventional acid regeneration facility. The alternative is to ship the spent acid to a large scale sulfuric acid plant serving multiple spent acid generators and to receive pure acid in exchange. This alternative is not particularly attractive when compared to the cost of fresh acid.

It is an advantage of the present invention is that it provides an economically acceptable method for the onsite regeneration of spent sulfuric acid. It is another advantage that the present process provides an environmentally acceptable method for the onsite regeneration of spent sulfuric acid.

SUMMARY OF THE INVENTION

Briefly the present invention is a process for the regeneration of sulfuric acid contaminated with hydrocarbons and water to produce pure concentration acid comprising (1)contacting sulfuric acid contaminated with hydrocarbons and water with oxygen and preferably elemental sulfur in the presence of a vanadium containing catalyst in a reaction zone(2) maintaining at least a portion of the acid in the liquid phase, (3) converting hydrocarbon to carbon oxides and water, and converting sulfur and sulfur dioxide to sulfur trioxide, (4) recovering a liquid/vapor effluent from said reaction zone, (5) separating said effluent into a vapor stream and a liquid stream and (6) cooling and partially condensing the vapor stream to concentrate clean acid. Cooling and partial condensation of the vapor stream produces concentrated clean acid and a vent stream containing the carbon oxides and any excess oxygen in the feed. The concentration of the acid depends on the amount of sulfur, if any, added to the reaction zone and the amount of water in the reactor effluent.

BRIEF DESCRIPTION OF THE DRAWING

The FIGURE is a simplified flow diagram in schematic form of one embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The regeneration is carried out by reaction a liquid/vapor mixture of spent acid, sulfur and oxygen (or an oxygen containing gas) over a supported vanadia catalyst. The operating temperature is in the range of 650-750 ⁰ F and a total pressure of between 1 and two atmospheres. Residence time in the reactor and oxygen partial pressure is sufficient to ensure essentially complete conversion of the hydrocarbon contained in the spent acid to carbon oxides and the conversion of sulfur to sulfur trioxide. In the indicated temperature range and in the presence of excess oxygen virtually no sulfur dioxide is present at equilibrium. As used herein the term "excess of oxygen" is understood to mean an amount of oxygen necessary to react with the hydrocarbons, elemental sulfur and/or sulfur dioxide present in the reaction zone to convert all of said hydrocarbons and elemental sulfur and sulfur dioxide to carbon oxides and sulfur trioxide, respectively. For illustrative purposes the hydrocarbon is assumed to be a C ₂₀ paraffin.

C ₂₀ H ₄₂ + 30.5 O ₂ → 20 CO ₂ + 21 H ₂ O δH = -5,372,031 btu/lb mol

S + O ₂ - SO ₂ + 0.5 O ₂ ^* SO ₃ δH = -290,471 btu-lb mol

Phase equilibrium in the reactor and downstream separation units with respect to acid and water is governed by the following ionic equilibria while oxygen and CO ₂ are treated as Henry Law components.

H ₂ SO ₄ + H ₂ O - H ₃ O ⁺ + HSO ₄ - HSO ₄ ^" + H ₂ O - H ₃ O ⁺ + SO4 ⁼ 2 H ₂ O + SO ₃ - H ₃ O ⁺ + HSO ₄ ^"

The reactor is a vertically disposed vessel containing the fixed bed catalyst such as V ₂ O ₅ /K ₂ SO ₄ supported on silica which is known to catalyze the SO ₂ to SO ₃ reaction.

Referring now to the figure a more detailed description of the process is given with a material balance included in the TABLE. The stream numbers match those given in the figure.

Oxygen in stream 3, spent acid in stream 6 and molten sulfur in stream 7 are combined in feed stream 10 and fed to the reactor 100 which contains the fixed bed of catalyst 101 where the hydrocarbons are converted to carbon oxides and the sulfuric acid and sulfur are converted to sulfur trioxide. The feed stream 10 is combined with hot recycle acid in stream 16 at the top of the reactor 100. In a preferred mode of operation the reactor operates adiabatically with the outlet temperature controlled by the temperature and flow rate of the recycle acid. The effluent in stream 11 is phase separated in the reactor V/L separation drum 102 with the liquid phase being recycled to the top of the reactor via stream 16. In a preferred mode of operation the recycle acid mass velocity is in the pulse flow region to ensure good liquid/vapor mass transfer rates.

Pulse flow is obtained at high gas and liquid flow rates. The pulses are characterized by large mass and heat transfer rates. Increased catalyst wetting and a continuous mixing between parallel flowing rivulets diminish flow maldistribution. In addition, the formation of local hot spots is reduced, leading to an intrinsically safer process and diminished catalyst deactivation. The pulses continuously mobilize the stagnant liquid holdup to the point where its stagnant nature disappears. Since stagnant holdup represents about 10 to 30 percent of the total liquid holdup in trickle flow operations, its more dynamic character during pulsing flow enhances reactor performance. Axial dispersion is considerably less compared to trickle flow, due to effective radial mixing between the different parallel flowing liquid streams and disappearance of stagnant liquid hold up. Especially undesired consecutive reactions are reduced to lower levels due to better overall plug flow behavior. A further advantage of pulsing flow is much higher radial conductivity. In some cases, depending on the pulse frequency, significant changes in both yield and selectivity occur.

The main benefit with pulse regime reactor operation is that of increased mass transfer and heat transfer due to the associated turbulence produced. When the

catalyst physical characteristics are optimized and the reaction kinetics are not limiting, increasing mass transfer is a key to increasing the process performance.

The vapor from the reactor V/L separator drum 102 is taken as stream 17 and cooled and condensed before being passed to acid product V/L separator drum 104. During the cooling and condensation process SO ₃ and water combine to form sulfuric acid which is removed as stream 18. The concentration of sulfuric acid in the final product stream 18 is dependent upon the amount of sulfur added to the reactor feed together with flow rate and composition of the spent acid stream.

Stream 19 from the acid product V/L separator drum 104 contains the carbon oxides produced in the the reactor 100 together with any excess oxygen and trace amounts of sulfur oxides. The sulfur oxides are removed by countercurrent washing in absorber 106 with 96% sulfuric acid in recycle stream 31 taken from the liquid product stream 28, and a requisite amount of water from stream 20. Slip stream 30 is the net amount of 96% sulfuric acid produced in the tail gas washing step.

As shown the carbon oxides and excess oxygen are simply vented to the atmosphere in stream 21. An alternative is to separate the oxygen from the carbon oxides, e.g., using a hot carbonate wash, and recycling the recovered oxygen via a compressor to the reactor.

In a preferred mode of operation the stream 2 oxygen feed rate is in excess of that required by the reaction stoichiometry. The excess oxygen also controls the V/L split in the reactor V/L separator drum 102. In another preferred mode of operation the oxygen rate is adjusted such that the net acid product is recovered in stream 17.

TABLE

2 6 7 10 11 16 17 18 19 20 21 28 30 31

Temperature F 100 100.1 400.1 675 680 575 150 150 150 105 109.45694 122.31196 138.5 105

Pressure psi 20 20 20 20 15 30 15 15 20 20 15 20 30 17

Vapor Frac 1 0 0 0.858 0.229 0 0.43 0 0.999999 0 1 0 0 0

Mass Flow Ib/hr

H2O O 375.078 0 375.078 1036.23 32.252 0 0 2.65E-08 27.27333 8.30E-05 4351.4711 6241.661 4324.196

H2SO4 O 11249.95 0 11249.95 99474.46 85455.88 19139.64 19139.6 0.033793 0 0.0040234 4.7391485 0.034 4.709379

H3O+ O 0 0 0 4507.331 4489.33 0.054 0.054 0 0 0 0 0 0

HSO4- O 0 0 0 22998.63 22906.78 0.275 0.276 0 0 0 0 0 0

SO4-2 0 0 0 0 1.057 1.053 0 0 0 0 0 0 0 0

S03 O 0 0 0 4823.575 206.178 155.534 56.72 98.81541 0 0.0003195 15766.046 0 15667.23

02 10000 0 0 10000 2810.642 1.513 2809.123 9.775 2799.349 0 2799.3474 0.1887371 0.046 0.187555

C02 0 0 0 0 2732.773 7.019 2725.727 71.287 2654.446 0 2654.4224 3.697035 1.034 3.6739

N-EIC-01 0 875 0 875 0 0 0 0 0 0 0 0 0 0

SULFUR 0 0 2784.868 2784.868 0 0 0 0 0 0 0 0 0 0

SODIUM 0 0 0 0 0 0 0 0 0 0 0 0 0 0

NA2SO4 0 0 0 0 0 0 0 0 0 0 0 0 0 0

NA2CO3 0 0 0 0 0 0 0 0 0 0 0 0 0 0

NAOH 0 0 0 0 0 0 0 0 0 0 0 0 0 0

NA+ 0 0 0 0 0 0 0 0 0 0 0 0 2298.978 0

OH- 0 0 0 0 0 0 0 0 0 0 0 0 0.009 0

HC03- 0 0 0 0 0 0 0 0 0 0 0 0 1389.751 0

C03- 0 0 0 0 0 0 0 0 0 0 0 0 2317.17 0