NL9002524A - Quenching high temp. gas or vapour stream contg. acid or alkaline cpds. or salts - carbon@ black and/or tar, and suspended solid particles by mixing with cooling two phase mixt. of aq. phase and hydrocarbon phase - Google Patents

Abstract

Gas or vapour streams at high temp., contg. acid or alkaline cpds. or their salts, C black and/or tar, and suspended solid particles, are quenched by mixing with a coolant liq. comprising a 2-phase mixt. of an aq. phase and a hydrocarbon phase.

Description

A method for quenching high temperature gas or vapor streams containing gaseous acidic or alkaline compounds or salts thereof, carbon black and / or tar and suspended solids.

The invention relates to a method of quenching high temperature gas or vapor streams containing acid or alkaline compounds or salts thereof carbon black and / or tar and suspended solids by mixing the gas or vapor stream with a cooling liquid.

A wide variety of industrial engineering processes produce high temperature gas or vapor streams containing gaseous acidic or basic compounds or salts thereof and suspended solids which must be vented or vented into the atmosphere before they can be used or reprocessed are deterred in order to be able to separate and recover the useful components present therein and / or to remove any harmful components and, if desired, to recover the useful components therefrom in useful form.

Important gas or vapor streams to be quenched include, for example: high temperature gas or vapor streams formed in refineries containing light hydrocarbons containing 1 to 3 carbon atoms, hydrogen sulfide and often also catalyst residues and fine soot or tar particles (see Kirk -Othmer, Encyclopedia of Chemical Technology, 3rd ed. Vol. 13, page 189 et seq., New York, 1982); hydrogen, CO 2, CO 2 and carbon black or tar-containing gas streams, formed during the thermal gasification of coal and heavy hydrocarbon fractions, (see Kirk-Othmer, 3rd ed. vol. 12, p. 952 ff., New York 1980); gas or vapor streams generated during the combustion of waste materials in waste incineration plants containing fine solid particles (fly ash, smoke particles, partially oxidized hydrocarbons, soot and tar), acidic gases (nitrogen oxides, sulfur oxide, hydrogen halides) and sometimes also heavy metals (see Kirk-Ohmer, 3rd ed., Vol 13, p. 185 ff., New York, 1981); in the pyrolysis of waste by cracking in the vapor phase, for example in the presence of hydrogen, gas or vapor streams formed, containing light hydrocarbons, hydrogen halides and soot and / or tar (see EP235.473 and DE A 3517864); gas and vapor streams formed in the thermal or catalytic hydrodehalogenation of halohydrocarbons (HKWs) containing waste materials containing hydrogen, light hydrocarbons, hydrogen halides and carbon black and / or tar and optionally metal-containing catalyst residues (see EP 175.406 and NL 8402837).

In quenching such gas or vapor streams, water is widely used, which is an inexpensive and readily available coolant and which has favorable heat of evaporation and specific heat.

In some cases, instead of water, liquid hydrocarbons are also used as a quench coolant. According to EP 175406, in practice, hydrocarbons with a boiling point between 60 and 100 ° C, such as benzene and heptane, are used, because this prevents problems with corrosion of mixtures of water (vapor) and hydrogen halides.

It has now been found that a particularly good deterrent effect is obtained when a two-phase mixture of an aqueous phase and a hydrocarbon phase is used as the cooling liquid. When such a two-phase mixture, in which one phase is dispersed as more or less large droplets in the other phase, is mixed with a quenched gas or vapor stream, the gas or vapor stream is quenched, that is, cooled rapidly by the gas - or vapor mixture critical range so that the composition of the stream is frozen and then slowly cooled further and acidic or alkaline compounds or salts thereof present in that gas or vapor stream are absorbed in the aqueous phase and thus separated from the gas or vapor stream after which they can be won if desired. Suspended solid particles present in the gas or vapor stream, especially carbonaceous particles, such as carbon black, and tar-like materials often formed in the processes mentioned, are well wetted by the hydrocarbon phase and are thus captured from the gas or vapor stream.

As the aqueous phase, water can be used successfully, but also an aqueous solution of acidic or alkaline compounds or salts; Acid or alkaline compounds present in the gas or vapor stream are absorbed more quickly into a dilute solution of those compounds, while when using water the absorption of acidic or basic compounds proceeds more slowly.

The hydrocarbon phase may consist of a single hydrocarbon or a mixture of hydrocarbons, which preferably has a higher boiling point or boiling range than the aqueous phase, i.e. a boiling point or boiling range above 100 ° C. This ensures that little evaporation of the hydrocarbon phase occurs, while hydrocarbons with a boiling point or boiling range above 100 ° C moisten the soot and / or tar present in the gas or vapor stream more easily than hydrocarbons with a boiling point below 100 ° C and thus carbon black and / or tar and any further solid particles from the gas or vapor stream are collected and dispersed in the hydrocarbons.

This moistening effect on soot and / or tar is best with aromatic hydrocarbons and therefore a hydrocarbon phase consisting of one or more aromatic hydrocarbons is preferably used. Most preferably, that hydrocarbon phase (for the most part) consists of one or more polycyclic aromatics, because they have the most favorable boiling points.

The composition of the two-phase mixture can vary within wide limits, which depend on the mutual solubility of the aqueous phase in the hydrocarbon phase and vice versa. In practice, however, the two-phase mixture preferably consists of 10 to 90 vol% aqueous phase and 90 to 10 vol% hydrocarbon phase, and in particular 30-70 vol% aqueous phase and 70-30 vol% hydrocarbon phase. Just a composition within these limits, any acidic or alkaline compounds or salts thereof are well absorbed by the aqueous phase from the gas or vapor stream, good separation of soot and / or tar and other solid particles from the gas or vapor stream is achieved and the deterrence is optimal.

Depending on the composition of the gas or vapor stream to be quenched, the best results are achieved with a volume ratio of aqueous phase to hydrocarbon phase between 40:60 and 60:40.

Mixing of the quench gas or vapor stream with the two phase mixture of aqueous phase and hydrocarbon phase can be done in any suitable manner for contacting gas or vapor with liquid.

Preferably, the gas or vapor stream is introduced into the two-phase mixture. The gas or vapor then bubbles up through the two-phase mixture as bubbles, whereby this two-phase mixture is intensively mixed together and the dispersion of more or less large droplets from one phase into the other phase is formed and maintained, and an intimate contact between the gas or vapor and both phases of the two-phase mixture is effected.

The two-phase mixture is kept at a suitable temperature during quenching of the gas or vapor stream, which is generally at least 10 ° C below the boiling point or initial boiling point of the two-phase mixture. In practice, depending on the composition, the two-phase mixture and the operating conditions during quenching are between 30 and 100 ° C. For example, for a two-phase mixture of water and diaromatic hydrocarbons (DAKs), the temperature is conveniently maintained at 60-80 ° C when operating under a pressure of 5 bar. At atmospheric pressure, the temperature in this case should be less than 60 ° C.

The temperature of the two-phase mixture is suitably controlled by indirectly cooling the liquid two-phase mixture in the quenching container, for example by means of cooling elements reaching into the two-phase mixture or by means of a cooling jacket around the container. However, the biphasic mixture can be kept particularly suitable at the temperature desired for quenching by circulating a flow of the biphasic mixture through a heat exchanger placed outside the quenching container. The temperature can hereby be controlled excellently, while at the same time an amount of the biphasic mixture loaded with soot and / or tar and any further solid particles can be extracted from said circulation flow in order to remove the components originating from the gas or vapor stream and to thus remove it. recycle regenerated biphasic mixture.

The invention is elucidated with reference to the figure which gives a block diagram of a preferred embodiment of the cooling and quenching stage according to the invention.

An acidic or alkaline compound or its salts and suspended carbon black and tar-containing gas stream is passed through line 1 in an amount of a two-phase mixture of an aqueous phase and a hydrocarbon phase contained in a quench cooler 2.

The gas bubbles up through the two-phase mixture as gas bubbles, whereby the two-phase mixture is vigorously mixed together and a dispersion of droplets from one phase into the other forms, and the gas stream comes into intimate contact with both phases of the two-phase mixture.

The gas stream thus quenched and cooled leaves quench cooler 2 through line 3 and can then be upgraded in some suitable manner.

A flow of the two-phase mixture with acidic or basic compounds absorbed in the aqueous phase and soot and / or tar collected in the hydrocarbon phase is continuously removed from the quench cooler 2 by means of a pump (not shown) via line 4 and through line 5, heat exchanger 6 in which it is cooled and conduit 7 recycled. In order to keep the temperature of the two-phase mixture in the quench cooler at the desired level.

Part of the flow of the two-phase mixture through line 4 is removed from the system through line 8 to separate and recover the acidic or alkaline compounds from the aqueous phase and carbon black and / or tar collected from the hydrocarbon phase therein after which the regenerated water phase can be discharged or recycled and the regenerated hydrocarbon phase can be recycled.

Claims (11)

A method for quenching gas or high temperature vapor streams containing acidic or alkaline compounds, or salts thereof carbon black and / or tar, and suspended solids, by mixing the gas or vapor stream with a cooling liquid, with characterized in that the coolant used is a two-phase mixture of an aqueous phase and a hydrocarbon phase. A method according to claim 1, characterized in that the two-phase mixture consists of water and a hydrocarbon phase. Method according to claim 1, characterized in that the two-phase mixture consists of an aqueous solution of acidic or alkaline compounds or salts and a liquid hydrocarbon phase. A method according to any one of the preceding claims, characterized in that the hydrocarbon phase has a higher boiling point or boiling range than the aqueous phase. A method according to any one of the preceding claims, characterized in that the hydrocarbon phase consists of one or more aromatic hydrocarbons. A method according to any one of the preceding claims, characterized in that the hydrocarbon phase consists for the most part of one or more polycyclic aromatics. A method according to any one of the preceding claims, characterized in that the two-phase mixture consists of 10 to 90 vol% aqueous phase and 90 to 10 vol% hydrocarbon phase. Process according to claim 7, characterized in that the two-phase mixture consists of 30 to 70% by volume aqueous phase and 70 to 30% by volume hydrocarbon phase. Process according to claim 8, characterized in that the volume ratio of aqueous phase to hydrocarbon phase is between 40:60 and 60:40. Process according to any one of the preceding claims, characterized in that the gas or vapor stream is introduced into the two-phase mixture of aqueous phase and hydrocarbon phase. Method according to any one of the preceding claims, characterized in that the two-phase mixture is cooled during quenching.