DE1468161C - Process and device for splitting hydrocarbons to acetylene, ethylene, methane and hydrogen with the help of hydrogen heated in an electric arc - Google Patents

Description

1 2

The present invention relates to a method of concurrent hydrocarbon exposure and a device for splitting carbon from hydrogen heated in an electric arc Hydrogen with the help of hydrogen, which is emitted in part and the radiation of the same arc introduced into an arc burn zone, zen. In another known method the on-site heated and in a manner called conductive by the arc lamp 5 is the one in the arc zone spatially separated, but directly heated hydrogen in the burning zone in the adjacent area Reaction zone is introduced. the reaction zone with the gas or vapor conveying

A number of processes have been brought together for the splitting of starting moderate hydrocarbons,

Hydrocarbons with the help of the electric light - the one at the far end of the reaction zone

bogens has already become known. So z. B. introduced tangentially at io and in a screw movement

those in German patents 806 455 and gung along the wall of the reaction zone

871 001 described method liquid output initially counterflows to the heated hydrogen,

hydrocarbon through the arc gap followed by the at the other end of the reaction zone

drifted, with hydrogen at the same time a reaction mixture reverses its direction of movement

blown or a hydrogen-containing or an inert 15 and along the central axis of the rotationally symmetrical

Keeping the atmosphere in the reaction space see reaction zone with increasing flow

will. However, this creates large amounts of velocity flowing into the post-reaction zone

By-products that reduce the yield, before and finally quenching. The hydrogen

The soot build-up is particularly significant. is introduced in such a way that a first

In the German patent specification 587 129, a 20 partial stream at the upper edge of the arc burning

Process for the splitting of hydrocarbons zone tangentially into these and other substreams that

and a device for carrying out the process- electrodes uniformly enveloping and along the

rens described. In this process, the same is introduced into the arc burning zone.

an arc created by two opposite each other. From this kind of introduction and heating

vertically arranged and hollow electrodes of the hydrogen is also used in the present invention.

Troden is led, hydrogen sent, which is used in the discovery.

an electrode is inserted and it is at the light- The present invention consists of the known arc base leaves through an opening. After becoming opposite in that at the inflowing When the arc passes through, the heated water enters the reaction zone flowing through it hydrogen through an opening of the other electrode in 30 hydrogen a first portion of the gas or the latter one. At the same time, at the upper end of the vaporous starting hydrocarbon in the form Fission furnace liquid hydrocarbon introduced, a cone jacket with a in the direction of the Ströder The tip lying on the inside wall of the cracking furnace flows down from the heated hydrogen and thereby in the arc burning zone from and immediately afterwards, also at the beginning Arc and the heated hydrogen heated 35 the reaction zone, a second portion of the gas is, or vaporous starting hydrocarbon

Since the contact area between the heated tangential into the reaction zone and the hydrogen and the hydrocarbon to be heated - the fission product emerging from this is relatively small in itself and the contact time is quenched in a known manner,
are short, the heat transfer from the hot 4 ° The first portion of the gaseous or vaporous hydrogen to the desired hydrocarbon starting hydrocarbon becomes with a Ströbrig. From this it follows that the hydrogen leaves the reaction speed of about 20 to 400 m / sec in the reaction space before it transfers its heat into the reaction zone in a conical direction; could give off the hydrocarbon, so that the- introduced. For hydrocarbons of low ses process only with a low efficiency 45 molecular weight, such as. B. Methane, one chooses to operate is. The hydrocarbon also comes very close to the arc at the speed range of about 100, so that an immediate 400 m / sec and, for gasoline hydrocarbons, the mid-contact between the hydrocarbon and the light composition C ₆ H _14, the speed arc is to be feared. As a result, the cohesion range can range from about 50 to 150 m / sec. These form velocities, which are distributed as soot in the carbons with their upper values approximately hydrogen or are deposited as coke on the elec- trodes in the order of magnitude of the velocities of sound, whereby the yield of acetylene in the substances concerned,
and ethylene is severely affected. The second part of the gas or vapor

In the process according to the German patent gene, the starting hydrocarbon is tangential with

Document 1 064 945 are hydrocarbons and 55 a flow velocity of 100 to 250 m / sec

Combustion gases are introduced into the reaction zone at the same time in a combustion zone. In the individual case

space, where the speed to be selected expediently depends on partial combustion

Hydrocarbons necessary for its cleavage, similar and in the same sense as in the conical

dense heat is generated. Around carbon deposit-shaped inflow, of molecular weight

gen on the wall of the combustion chamber to 60 of the respective starting hydrocarbon.

avoid, the wall is rinsed with water. The flow threads of the cone-shaped

Care must be taken that the flowing first part of the gas or steam

Rinse water in sufficiently large quantities and with shaped starting hydrocarbons intersect

high speed along the wall of the reaction zone at an angle from 90 °,

Combustion chamber flows to an evaporation of the 65 corresponding to an angle to the horizontal to

Water to prevent. 45 °, in one point. The entirety of the flow

It is also known that a rotating, thin filament lies on the lateral surface of a

n, constantly renewing film of the liquid straightening circular cone, the tip of which points in the direction of the

3 4

Flow of heated hydrogen shows. Through the ring slot with an angle on the same up

the cone-shaped introduction of the first part 45 ° executed.

amount of gaseous or vaporous starting carbon This is followed by one surrounding the reaction space Hydrogen in the flowing hot hydrogen ring channel, which is carried through outflow openings an intimate mixing of the two substances 5 tial are incorporated, with the reaction space in reached, while through which stands immediately after the cone connection. As a result, the second part of the jacket is shaped intended tangential introduction amount of gaseous or vaporous output of the the second part introduced an effective purging of the hydrocarbon. Inner surface of the reaction space takes place so that at the entrance of the to the reaction space of carbon Deposits on this are prevented The ingress of hydrocarbon vapors radial introduction of the quenchant into the stream the arc burning zone, the hot fission product provided in this coal end, which is in a Could cause substance deposits, is according to the invention perpendicular to the central axis of the entire device according to a suitable choice of the flow velocity level.

abilities of the hydrogen and the first subset 15 The for carrying out the process according to the invention

of the starting hydrocarbon as well as the angle, driving serving device is in the drawings

below which the flow threads of this are shown conically schematically.

The first subset in FIG. 1, which is retracted in the form of a jacket, schematically shows a meridional section

Cut the reaction space, bent forward. by the device according to the invention;

A cross section through the device is shown for heating the 20 FIG. 2 supplied in partial flows

Hydrogen in the electric arc are depending on the section plane II-II, from which the structural

Nm ³ hydrogen 2 to 7, preferably 2 to 5 kWh Details for the tangential introduction of the

expended. Hydrocarbons emerge;

The cleavage product is in the quenching zone in Fig. 3 shows a cross-section through the Vonichsich in a known manner with the aid of a radial direction according to the section plane III-III and the radial quenching agent sprayed in. Here- introduction of starting hydrocarbons, for has the use of a paraffinic oil, the arc combustion chamber 1 in FIG. 1 exists for example a paraffinic heating oil distillate, essentially consisting of one in the intermediate piece 9 proven. incorporated circular cylindrical cavity, the un-The device for carrying out the invention is open and its upper limit by the according to the method consists of an equiaxed cover 2 is formed. Through these are the A string of electrodes 3, which is known per se, is passed through and held in it, designed, open at the bottom, with feedthroughs. and holders for the electrodes as well as with a single inlet channel 4 free through the hydrogen, Flow openings for hydrogen provided light- 35 enveloping the electrode, in the arc combustion chamber, a subsequent circular chamber is introduced.

cylindrical, open at both ends reaction between the cover 2 and the space and an adjoining circular piece 9 is a distributor ring 5 for the introduction cylindrical, at both ends open quenching arranged further amounts of hydrogen, which with space for quenching the fission product. 4 ° an annular channel 6 is provided.

The arc chamber is in its individual This is through a feed line 7 with a

already in the German patent specification 1168 419 hydrogen source and by a number evenly

described by the inventor and is essentially distributed in a circle of outflow openings 8, the tan-

union parts taken over unchanged.

from a circular cylindrical, cooled chamber, the 45 with this in connection.

open at the bottom and through a cover at the top is closed, provided in the passage openings for the. The arc chamber 1 is followed in Electrodes incorporated and holders for these arranged in the direction of flow of the heated hydrogen part are. At the upper edge of the arc currents, the intermediate ring 11 with the ring channel 12, Combustion chamber are inflow openings for hydrogen 50, the annular slot 13 and the coolant channel 14. For provided, and the electrodes are special by introducing the first subset of the starting pods passed through, which is used to feed further hydrocarbons into the annular channel 12, the feed substreams of hydrogen along the electrodes in line 15. The annular slot 13 is in the flow die Allow arc combustion chamber. direction of the heated hydrogen or the Re-intermediate This and the reaction space is inclined to 55 action mixture, so that the out of it Next, an all-round ring slot is arranged, the starting hydrocarbon escaping is the jacket Meridional section forms the surface of a straight circular cone adjacent to the base, the tip of which Part of the surface line of a straight circular cone, which lies on the central axis of the reaction chamber 19 sen tip in the direction of flow of the reaction A cross-section through this arrangement after the mixture on the central axis of the reaction chamber 60, section plane III-III is shown schematically in Fig. 3, is equivalent to. This ring slot is used for insertion.

tion of the first subset of the gas or steam conveying In which the intermediate ring 11 is connected

migen starting hydrocarbon in the conical distributor ring 16, an annular channel 17 is incorporated.

shaped direction in the flowing heated water, which works in a to the central axis of the reaction substance, where the flow threads lie in their common space 19 perpendicular plane and with tangential

seed point of intersection on the central axis of the reac- tial in the same outflow openings

have space. 18 for the second part of the starting coal

Based on the base of the straight circular cone, hydrogen is provided. For the introduction of

The same in the annular channel 17, the supply line 26 is arranged. This arrangement according to section plane H-II is schematically in FIG. 2 shown.

The reference numerals 28 in FIG. 2 and 29 in FIG. 3 denote flow threads of the starting hydrocarbon flowing through it.

The reaction space 19 is in the externally cooled reactor body, which consists, for example, of graphite 20 incorporated.

Following this, an intermediate ring 21 provided with an annular channel 22 is arranged, the Annular channel 22 narrows towards the bore of the intermediate ring to an annular slot 23, the plane of which is perpendicular to the central axis of the entire device. For feeding the quenchant into the feed line 24 serves the ring channel.

The last link in the sequence is the quenching space 25 incorporated in block 27, in at which the freezing of the new chemical equilibrium obtained by the fission process comes to an end to be led.

The cleavage product obtained is finally worked up in a manner known per se.

On the drawing F i g. 1 are two electrodes 3 as they are for the use of direct current or single-phase alternating current come into question, shown. However, the arrangement can be given different power supply ratios also with a different number of electrodes, for example with three electrodes for three-phase current.

example

In an electric high-current arc, which is maintained in a water-cooled arc combustion chamber 1 between three graphite electrodes 3 and converts an electrical power of 2250 kW, 750 Nm ^{3 of} hydrogen are heated up every hour. They are retracted in such a way that they have a flow velocity of about 70 m / sec at the inlet end of the reaction chamber 19. From a water-cooled ring slot 13, .800 kg of gasoline with the boiling point 40 and 130 ° C per hour are injected in vapor form into the heated hydrogen. The direction of injection is chosen so that the hydrocarbon jet in the direction of the reactor outlet is inclined by 30 ° relative to the horizontal. The cross section of the annular slot 13 is dimensioned so that an exit velocity of the hydrocarbon of 160 m / s is achieved. Immediately below the ring slot 13 there are six outflow openings 18 through which another 200 kg of hydrocarbon vapor per hour are tangentially introduced at a speed of 200 m / sec.

The cleavage product is quenched in annular slot 23 through radial injection of 50 m ³ per hour of a paraffinic distillate fuel oil whose boiling ranges are 180-350 ⁰ C. There are ■ 1900 Nm ³ of cracked gas per hour with an acetylene content of 11.5 percent by volume and an ethylene content of 9.5 percent by volume. Soot deposits are not found anywhere.

Claims (8)

Patent claims: 1. Process for the splitting of hydrocarbons into acetylene, ethylene, methane and hydrogen with the help of in electric light • '. arc-heated hydrogen, which is introduced in partial flows into an arc-burning zone, heated there and introduced into a reaction zone spatially separated from the arc-burning zone but immediately adjacent to it, characterized in that at the inlet • of the reaction zone in the hydrogen flowing through it first partial amount of the gaseous or vaporous starting hydrocarbon in the form of a cone shell with a tip lying in the direction of the flow of the heated hydrogen and immediately thereafter, also at the beginning of the reaction zone, a second partial amount of the gaseous or vaporous starting hydrocarbon tangentially introduced into the reaction zone and that from this emerging cleavage product is quenched in a manner known per se. 2. The method according to claim 1, characterized in that the cone-shaped inflowing first partial amount of the gaseous or vaporous starting hydrocarbon with a Flow velocity of 20 to 400 m / sec, preferably 50 to 150 m / sec, and the tangential inflowing second part of the same with a flow rate of 100 to 250 m / sec is introduced into the reaction zone. 3. The method according to claim 1 and 2, characterized in that the cone-shaped inflowing first partial amount of the gaseous or vaporous starting hydrocarbon at an angle to the horizontal up to 45 ° in dei The direction of flow of the reaction mixture is introduced into the reaction zone. 4. The method according to any one of claims 1 to 3, characterized in that 2 to 7, preferably 2 to 5 kWh ^{per Nm 3 are expended for heating the hydrogen in the electric arc.} 5. The method according to any one of claims 1 to 4, characterized in that as a quenching agent a paraffinic oil for the cleavage product, for example a paraffinic heating oil distillate, is used. 6. Device for performing the method according to one of claims 1 to 5, consisting from an equiaxed juxtaposition of one designed in a manner known per se, according to Open at the bottom, with feedthroughs and retaining rings for the electrodes (3) and with inflow openings (8) for hydrogen provided arc combustion chamber (1), a subsequent one circular cylindrical, open at both ends Re- . .. action room (19) and one adjoining it circular-cylindrical quenching space (25) open at both ends for quenching the fission product, with an arc combustion chamber between (1) and reaction chamber (19) devices (13, 18) for introducing the gaseous or vaporous starting hydrocarbon into the reaction space (19) and a device between the reaction space (19) and the quenching space (25) (22,23,24) provided for introducing a quenching agent into the quenching space (25) 'are characterized in that for the introduction of the gaseous or vaporous starting hydrocarbon between the arc combustion chamber (1) and the reaction area (19) there is a circular slot (13) running around 11m, the meridian of which intersected the part of the generatrix of a right circular cone adjacent to the base, its Tip in the direction of flow of the reaction mixture lies on the central axis of the reaction space (19), corresponds to, arranged and followed is tangential to an annular channel (17) lying in a plane perpendicular to the central axis outlet openings (18) for the gas or vapor form opening into the reaction space (19) Starting hydrocarbon. 7. Apparatus according to claim 6, characterized in that the annular slot (13) accordingly an angle of up to 45 ° is incorporated at the base of the straight circular cone. 8. Apparatus according to claim 6 and 7, characterized in that at the entrance of the quenching chamber (25) an annular slot (23) lying in a plane perpendicular to the central axis for radial introduction of the quenching agent into the flowing hot fission product is provided. 1 sheet of drawings 009 548/428