DE1543204A1 - Process and incinerator for the production of unsaturated hydrocarbons from saturated hydrocarbons by means of thermal decomposition through flame reaction - Google Patents

Description

MAGYAR ASVAHYOLAJ ES FÖLDGAZ KISERLETI INTEZET in Veszpr € m (Hungary)

Ye »fa.h» e.n and Vearbrennungeinriehtung? For the production of unsaturated hydrocarbons from saturated hydrocarbons! by means of theraic decomposition through planar reaction

It is known from saturated hydrocarbons or from mixtures of "saturated" hydrocarbons unsaturated hydrocarbons or their Oentisohe may tbermlsohe decomposition hersuitellsn. During the thermlaohen

386 / 16.alt. _ ^

001021 / 1S4I 'BAD ORIGINAL

Decomposition can also affect unsaturated cofalena saturated hydrocarbons of smaller carbon atoms number, hydrogen and carbon, further in equivalent τοΛ Oxygen and oxygen-containing compounds charcoal Carbon dioxide and other oxidation products are formed. * Thermal decomposition is necessary; ** ota the dis-

Working temperature between 800 and 16OO ° C and the sweetest

—2 —3
short duration of 10 to 10 seconds. substantial heat consumption. As a result, the raw material to be decomposed has to be supplied with a large amount of heat within a very short time, which is one of the greatest difficulties in thermal decomposition.

A frequently used method of supplying heat consists in mixing the hydrocarbon to be decomposed with oxygen or another oxidizing substance in such a way that the lit ctee is partially burned Raw material directly (ipernii.itelte urine © ensures the heat requirement of the decomposition, tin be & mitoe example of this method is the partial oxidation of methane with the production of acetylene and Synthiaega bi « 6QQ ⁰ Q το * · warmed öemiseh of 63? ί OH. and

Öuroh there "" without freezing the Ubtr 14Θ0 ° 9 re * running

$ ■ ■ "

orird a 8.2 Vol.AieiyUn, wel ^ tr · Rj _f 00, 00 ,, OS ^

BATH

containing product obtained * The starting mixture roues in close to the upper flammability limit. At a lower one Oxygen concentration makes the combustion unstable, with a higher concentration, however, the oil weight conditions deteriorate the formation of acetylene. The reaction mixture of methane and Sauersteff has to be improved the formation of acetylene, as well as to reduce the acid consumption.es are preheated. The upper limit the preheating is limited by the ignition temperature of the methane

correct (645 ° C) · With the partial oxidation of methane "with the preheating of 6QO ⁰ C, which is still permitted for safety reasons, when using oxygen with a purity of more than 99 $" a specific acid consumption of 5 kg Gg / kg CpH- can be achieved By decreasing the purity of the oxygen, the specific oxygen consumption is increased considerably.

At * another significant group of the ther »· mixing decomposition, the endothermic and the decomposing reaction is carried out in two stages. These procedures are characterized by a nearly BtUohiometric mixture of any fuel gas and oxidizing substance - preferably a heating gas green water » steffhaltes and SaueTsteffes - is burned to the Protect the material, the temperature is there in this way resulting smoke gases from 2700 to 2900 C by adding Steam on sth ^! ^ Ssojfo h, what ^ gej? Etzt, then the-

BATH ORiQIMAL

According to the heat carrier gas, the hydrocarbons to be pyrolled are mixed in and the "Jö? odw: tgaee frozen in the known manner at the appropriate time. Animals of the high speed of thermal decomposition reactions have rough, the mixing of the hydrocarbons and the heat carrier gases must be extremely intimate * At the point of mixing Even the heat carrier gases. " as well as the hydrocarbons to be mixed, with a very high flow rate - generally corresponding to the speed of sound - and it has to be complicated ο versions. and Siev Qxydationsstoff with a "also dta? sound velocity corresponding öesohirindigiceit" are iiieinander vexmisoht. As a result of caused by the flue gas "high temperature Sehwlyr ^ / rkeite» »of Gressen energy consumption in the mixing and the duyeh increasing the proportions increasingly Kisohungein- occurring · inhomogeneities the economics of these processes will significantly deteriorate the one hand, on the other hand are "ur Durchfühn ^ - complicated Eeaktoren needed"

Oemäss the present Brf is di "him *" nisehe Zereetavmg of the saturated hydrocarbons in riamenrea ^ IION and accordingly * a * t * dt durehgeführt in a Stuf that aur generation of the Zersetmay indung: greater Heizgaee.

009820/1041 ^BAD

_- 5 - ■

and upper ignition limit than that of the hydrocarbons to be decomposed, be used. The essence of the invention is that the mixture of the hydrocarbons to be decomposed * the Heating gases and the oxidant together with the burner of the

Flame reactor are fed in a ratio such that combustion of the mixture, the reaction temperature is between 1000 and 16oo ° C falls, and at least 30 $, zweokmässig about 80 $ of the gene for the implementation of Beaktion amount of heat supplied by partial © of the total combustion 4p heating gases, then the The decomposition reaction is frozen immediately in a known manner after the formation of the respective desired unsaturated hydrocarbons,

Under the action of the heating gas mixed with the hydrocarbons to be decomposed, the combustion is generally more stable than with the usual partial oxidations. The thermal decomposition of the saturated hydrocarbons begins as a result of the higher combustion speed of the heating gas, the rapidly occurring decomposition temperature, but is only ended after the combustion of the heating gas used. The Faroe Islands are mainly "guaranteed" by the Eoiaga! And the 7th separation takes place in larger masts from the load of hydrocarbons only if after the combustion of the stligM nooh oxygen remains in the oetaisoh. old to 4 partial oxidationj a »··!« · t «kNhi liöb dt ·

Yield of unsaturated hydrocarbons, on the other hand the specific Saueretof fverbrauoh and the Bus formation.

As a result of the reaction, the main building products are acetylene or, at the same time, acetylene and ethylene. The byproducts are generally carbon dioxide, carbon dioxide, hydrogen and methane, etc. Hydrogen and carbon oxide are usually produced in an amount that exceeds the amount of heating gas required for heat generation. ^ The ratio of the produced from the su "replace hydrocarbons unsaturated hydrocarbons, mainly of ethylene and acetylene is" weokaässig by the decomposition temperature, this temperature contrast duroh the choice of abhtngigen of the respective quality Verhalt - .. Bisset of the saturated hydrocarbons, the Heisgase and the oxidizing agent set.

If the reaction time is longer than the sur Asch tylenbildung necessary adjusted and a little sweeping sour * substance used, sioh decompose the saturated ones fabrics completely and there is a vussfrele *

Ocmäsa the procedure that »· with ataosphirisohen and with small or large · * ·» »soflay mnh tteef to lU teuok can be carried out,

■ 7-

on the other hand, the quality of the starting material changed significantly will. The reaction conditions are given by the starting etoff) the hot gas, the quality of the oxidation substance and determined by their relative amount '. Sas relationship between Acetylene and ethylene depend on the starting material, on the react ion temperature and the reaction time. The procedure is also feasible when the amount of the saturated carbon ' Hydrogen added fuel gas smaller or larger than is necessary for the formation of heat.

It is moderate, the less oxygen demanding Select heating gas BU, through which combustion products are fed to the reaction mixture} the Equilibrium conditions affect the thermal fission, since in this way the profitability of the Processed characterizing specific oxygen consumption be * can be significantly improved. The de * Heizgas compared to the invention Requirements can be derived from the combustion characteristics of the saturated raw material used Hydrocarbon and fuel be based on some hydrocarbons and heating materials as well as based on pure oxygen in the following Table are included

2s it was found that it is advantageous in the »process» the hydrocarbons, pickling gases and the oxidizing agent to a temperature of 400 to 600 C pre-uwSr-

BATH

008829/1646

• men. The components are either individually before bending. or the hydrocarbons and heating gases are preheated together and the separately preheated one is used to mix them Oxidizing agent oeigemisoht. Preheating can also be done after prior mixing of the components take place.

Material r _& Z _Q ψ% ψ%

420 59.2 4275 0.803 3440 - 50.5 4390 0.617 358Ο 365 55.0 4460 0.822 3665 480 49.0 4550 0.825 3750 - 28.8 * / 4360 0.820 3580 109 93.3 6040 0.785 4750 1120 93.9 5140 0.805 4140 - - 4280 0.846 3 * 35 2?:> O 0 * 673 1700

^x 'The indication "refers to petrol.

τ. om / eeo maximum. Burning obscurity

Z ", YaI. $. Note Zündgrenjse

γ 1εο · 1, Ίϊΐη O ₂ ipeeifiephe wax formation * uf i «uer-

• toff
91 without dimension Effectiveness of Fetterungeteeiwiik

009821/1 ^ 4

- 9 -
a reaction temperature of 1200 ° C

Ut) keal / Nm O ₂ the economic efficiency of the formation of heats

kennzdr-? " ¹ ». on the product.

As can be seen from the data in the table, the hydrogen corresponds to all the requirements placed on the heating gas, and experience has shown that even the presence of the water vapor produced by the combustion is effective. favorable to the cereal reaction because the water vapor reduces the harmful side reactions, especially the excretion of carbon. Carbon oxide entepx-ioä.t «-.- ■■ besides» can be used as heating gas because of its slow burning with hydrogen including hydrogen / You VexviaQhratg the carbon oxide with the decomposing Köhlenwaesersf eciTa ^ is in the oyster line therefore only ζ height, φ » 11 thereby in ■ :::. ' therftisehen 2 * 3 »eetzuftgfsre * lrti <« i die image ««? 4e »Kohl * r, <·. ~ S ras. Significantly reduced virdi wb.b laijt dor the table an exceedingly »umrir-cschaftliofcer Bs» ei noofe mentioned, d »» s the

at we lohen the "le J &x" g & ngug ", v 1jer. ^ fita" Ketha "only I ₄ O Vol.jS gas
Carbon dioxide,

feite masse " dft *" eaigjx- 4 "£ i? di439 ^ & s3! 3 Ae * i.j'i" cftVi W? * o'find i »doek small do ·« » for d & s Srvet« li «rft«? ^ de?

- LO -

suitable.

By dosing the amount of the oxidizing substance In certain cases, ββ can be advantageous in the reaction

the de _r respective Zuaammenseteung the introduced mixture corresponding upper .Zündgrenze "under homogeneous combustion conditions! to carry out «The amount of dee in» starting substance The oxidizing substance in the product gas «The oxygen concentration remaining in the air is regulated in such a way that the oxygen residue strisohan 0.2 and 0.5 "vol. $ fJUlt»

Kanu ein to carry out the according to the invention. During the partial oxidation of methane, HeaMox is extracted, dor iz; Fi.ilier _4> ngos Detd ▼ erhältnismiteeig much Heisgas be sugeführt nsuas "oftteig, -derart abgegjadert rird _f ίί-ββ" l ^ + * t 4 "e Rt * kter

»Afiuaen, · In which <^ & eu sisif« s1 »* it au? the heating gas and then the S ^ usrstaff

ve s ent height · part d «s? Ian» R5? 4 ^ «lRtc: e · is des ¹

Gegepietaad 4er Sy? Charge - iesr woe den , in the Abbiidime dejff ^ f ^ en ^ ftÄ & tti ¥ 5file & | , nmr · »ua

de «de« @tt »ü ^ T» ^ «n« nah «a '^ ff% i ^ 4«

It used to be narrowed in such a way that the mixture flowed through this cross-section at a greater speed than the burning speed, thereby preventing backburning into the diffuser _1. The full cross-section of the "section _2 was generally filled with a whole or parted refractory ceramic block" in which all narrowed free cross-sections were designed on the full cross-section, circular duroplastic fractures evenly distributed in the direction of flow. The cross-section of the Brennrauaee was chosen such that the flow geometry of the mixture was smaller than its burning speed "and thereby the formation of the stable flame ift Brennrats"

v ' ¹ ,

was rented. To ensure a more stable! ? laa 's and sur preventing Büofcbrennens was the ratio of the free cross-section dee section Z _- and the cross-sections "of the combustion chamber \ between 1x4 and It overall 12 for correspondingly \ found that Loohdurohmesser of section ^ were sveukmteeig Bwieöhen 7 and 10 em . In these devices, the dia-. ^; • ion of the ara meeting point of section Z narrowed transverse

V eohttittee and dee Brennraumee ^ lying Toträuae eo large, \

there, as a result of the office clearings, a substantial coke »Storage arises, which is often removed during operation «Rerdeft euee. I got a rewarded device and got rid of it "E"] UUiieohe · So have a "" e turned. Since «So have the Kokt * blage- # 18x4 on the one hand the start-up operation, on the other hand

. · ORIGINAL BATHROOM

Ö0S829 / 1646

a frequent slipping of the refractory material of section 2 caused.

Devices are also known for carrying out the flame reaction, in which the narrowed section 2 is made of metal and is cooled with water against the harmful heat stress radiated from the combustion chamber. In addition to their complex hollow design when crossing sections 2 and 3, these devices also have large dead spaces, which is why these are not advantageous either. Efforts are also known to provide boreholes of larger and smaller flow resistance in oil burners in order to form a protective flame. However, these devices are completely unsuitable for carrying out the flame reaction according to the invention and can only be regarded as an indication of channel systems of smaller and larger hydraulic resistance.

Öeinäss the invention, the narrowed cross • efanitt of AbsohnittöS Z ^ from joints, the attached through parallel, metal plates and, having a thickness eweokmässig zvisohen 1.5 and 3 na, a ^ are gegrenist siohtbaren and their dimensions by the sectional AWL , dietane holders formed from the plates are determined. The ratio of the fugue H and the slab varies slightly and 1 (2) so it is

de · free cross-sections · from paragraph 1 and dee from Brennraua χ weeentlieh smaller than. both

000829/1646 ^8AD

known devices. The erfindungagemäsee device also guarantees "with these conditions towards Rüok · * "burn in the diffuser a corresponding security and also provides a stable flame because of the dimensions of the Fugues £ were chosen in such a way that the Heynolds number in the eligible loads between the joints in the laminar} in the combustion chamber 3, however, in the turbulent area falls. This is advantageous because of the focal speed the same is much smaller in the laminar area than in the turbulent area) smell the ratio StrBuroage speed and the burning rate will therefore be eternal the joints larger, whereby the applied in the invention Cross-sectional proportions against back burning in the diffuser provide sufficient security.

The security against burning back the flame in the diffuser naturally also depends on the height of the plates. The greater the "security achieved" and the higher the level of communication to be expected in the system, the higher the number of plates open between the diffuser and the combustion chamber.

It diohte distribution of the joints. As a result · de »wteentlioh smaller t * Wl & * ttJ« e) tinitt »! Mn die htnti * h * li «h der Bti% mm§ * β * · η Η ^ Β * · 4 #? Ϊ́» βϊ ^ ei ».

ΒΑΠ

15432Ö4

. -U-daii vain coke deposit becomes uiimeglioh.

Up to the heat load on the flats is relatively small, since the ratio of the surfaces irradiated from the combustion chamber to the surfaces cooled by the surface flowing between the plates is very favorable (it varies between 1 * 50 and -1) 100). Correspondingly, the section I _{1 can be designed} with certainty from one, one, ^{bonding metal that does not exceed IQO 0} C and not more than IQO 0 C bond metal, without water cooling.

Another feature of the invention is that the free cross-section in narrowed free cross-section de Sections «£ formed by swel canal systems, duroh die dft qemiech at different speeds duroh * • flows. The one canal system, through the dtr predominant part

jT ι

de · gas mixture flows »consists of joints £ relatively large cross-sections where the flow is present - nd small? i »t | • So there was such a great flow of volatility errvioM who * 4eo did da · RÜokbrenntn the FlaratB »in the diffuser old 91 * before» h «it -reroed. On the other hand, the Strötnungsffesolttiindigkei * in dta, Sh de * ^ Utasshttltern auagtsteateten ltol «n eivgtr Que * $ i &» it $ e vefMl des gTua »@ren 3tr3amnfSTrid *» tUBd Kit Ins r W dvuroh «nt« pf «ohend »La» i «zuttf 4 · ν Avl« «

“Oil

'15432ÖA

but only "approach the burning speed" to the extent that the narrow hats do not allow the flame to burn back into the diffuser »which, by the way, is also inhibited by the cooling effect of the metal plates * Since the Gernlach flows out of the grooves J at a speed that might be less ale burn rate ", but certainly less istι than the cruising speed of the flame, the continuous burning is secured" because the mende from hats J, StrF>"mixture to the" out of which are in close saw the grooves joints \ with gröseerer The speed of the mixture flowing out continuously provides pilot flames.These pilot flames - distributed evenly over the full cross-section - ensure the stability of the burning process, which enables a large change in the load on the burner, since the load can be increased until the speed of the X the mixture flowing out reaches the rupture speed of the flame.

The following are used to carry out the procedure Examples 1 to 3 »For the design of the device, Examples 4 and 5 · Letetere are disclosed in connection with the known partial oxidation of methane»

Example I t

A gas mixture of the following composition, preheated to 4000, in an amount of (50 Nm / h and at atmospheric pressure) was added to the burner of the flame reactor

BATH CR. ^irs i '* JAL

003829/1646

»Ugled 31.8 1 ι Ox j as heating gas "CH.
4th 3.6 Il > as a gas mixture to be decomposed
t O ₂ H ₆ 1.5 H 1 as a contamination of the C ₃ E ₃ . '28.8 Il Hydrogen Hg " 27.2 M. as a contamination of the '° 2 ^, 3 It Hydrocarbons 1.8 ' η co ₂

Partial combustion of this gas mixture with the oxygen contained in it resulted in a reaction temperature of about 1450 C. The reaction productsο were after a

—2
Response time of 3 · 10 βθο. Quickly cooled with water to a temperature below ICO ⁰ O and 65 Nm per hour were obtained
dry product gas of the following composition:

C ₂ H ₂ 8.2 Vol. CO 17.2 η ^H 2 61.2 ti ° H ₄ 4.0 N ° 2 0.3 dd ^N 2 4.9 If 0O ₂ 4.2 »

The application of hydrogen as a healing gas

bath 009829/1646

So swr IH) IgQ) the "the one who knows the economic viability of the process * Ip worthwhile ipeeifiscüe oxygen consumption of - with the known partial oxidation with a preheating - of 6QO ⁰ C achievable - 5 kg, to 3> 75 kg O" / kg CgEg decreased, which can be reduced even more without the ITg contamination present in the Das specified "

It should also be noted that this result was achieved with a preheating of 40O ⁰ C, which is the case with the material

S-

Preheater and, when it comes to the heat requirement, the preheating means even more savings *

Example 2:

Sem burner of the flame reactor was also a pre-heated to 400 ⁰ C gas mixture ~ sannaens et ung * supplied with an "atmospheric pressure and in an amount of 60, .To / St, the following Z5i * t

CH, $ 30.5 vol. As "Often" to be "replaced"

CO 15.3 "", · ' _v

V al · HaiBgas _N % 32.0 «j '

O ₂ 22.0 '",:

ITj d _f 2 ^w alp V «» impurity det SaT * # ·

erstoff ··

Dicfoe da mixture was not contained with dtm in itAlteaea, '

8au "" e1ioff payliell among the realrfeio "ebe4ij ^ unf * ⁿ ro"

■■ *. ■;. ■ '-

game X Ye »bra» t and mn received per hour4 · 52.5 Vn ^ ηβ · ProduXtfM felgtader 3o «iuMi« aMt «un £ i / '

O ₂ H ₂

. co

co "

i- 18 -

9.3 Vol.ji 06 »1« 56.5 · »-

3.5 ^w

0.25 ^w

0.25 «

4.1 "

When using an oil gas tank containing the CO and the B. in a ratio of almost Is2 and using 99% oxygen as the oxidizing substance, the specific water consumption was reduced to 3.3 kg Q ^ / kg CgHg ^{when preheated to 4QO 0 C} . >

Example 3t

The burner of the yiammenreaktoxs a Oasgemisoh same amount and gleiohor Druofc- and Tejnjereturwerte as supplied jedooh following composition in currently "

OH.

00

20.4 vol

20.4 "^ '

42.5 ^w

Heisgfts

0.2

as an impurity d ·· ta ** eritoff ··

By partially burning this flftsgeaisoltt * ait the "oxygen contained therein, among the

T (Wed example 2 vutdf pvtf hour 47> 1 ** Irooiunee

■ t ·. · ■; * '■.

i- ■

»'·% ΡΓ1 ..

duct gas with the same composition as in Example 2 won. -

The further increase in the 'amount of fuel gas CO + -Η' in a ratio of nafiezu 1: 2 at the expense of methane means a further acidic saving, since the specific acidic gas achieved in this way required 2.76 kg of O ₂ Ag G is ₂ H ₂ .

It should be noted that in this case the amount of previously mixed GO + H «Gases slightly smaller than the" of the CO + Hg gas produced in the reaction, the CO, Η «and CH. Components of the product gases can therefore be used directly as raw materials for the reaction,

Example 4 » .

Through the burner, a gas mixture of 62.5 $ methane and 37 "5 $ oxygen was preheated to a temperature of ⁰ C 6OQ, performed with a pressure of 1.1 ata. The specific load on the narrowed free cross-section · des

3 2

Burner related was 200 Nm methane per dm .St. The height of the plates £ was 75 mm, the maximum temperature on the burner side 625 ° C. There was no coke deposit on the plates.The composition of the product gas obtained by the usual freezing of the reaction was:

Asetjrlen - 8.6 Vol. # '- Carbon Oxide 26.0 « Hydrogen 57 »5"

009829/16 ^ 6

Carbon dioxide 3.7% by volume '. Methane / 3.5 " Ethylene 0.5 " oxygen 0.2 µ Example $ i

In this case a gas mixture of 63% methane and 379% oxygen, preheated to 600 °, was passed through the burner at a pressure of 4%. The specific load, based on the restricted free cross-section of the burner, increased eieh due to the larger Druokes to 6OO Nm methane / dm .St. "The maximum temperature of likewise 75 mm high plates 4 increased SiOH still only to 65O ⁰ C on the burner side. In this case, too, there was no coke deposit on the plates

The composition of the product gas was with the

identical to example 1.

The data in Examples 4 and 5 relate to tests carried out in the, shown in the figure, with distant containersj5 and grooved braking device became. Similar results have been achieved than the Dietanah cooling elements and the channels j [from, resting on plates, however thinner, in the flow direction in places grooved panels corresponding to the width of the cavity, or made of ■ ep «rat inserted tubes designed with small diameters became.

0-0 9829/1646

Claims (1)

1543104 ~ 21 - FatenfenaprUohe ι ' 1. Process for the production of unsaturated hydrocarbons from saturated carbon dioxide, by means of thermal decomposition by flame aeat reaction, where fta? Instantaneous generation of the amount of heat required for the decomposition of hot gases with a higher combustion speed and upper ignition limit than that of the decomposing hydrocarbons are used »characterized in that the mixture of the carbons to be replaced, the hot gases and the oxidation« The fuel is fed to the burner of the flame actuator in a single ratio, so that by burning the mixture, the reaction temperature is between 1000 and IqOo ⁰ Q and at least 30 $, two times more than 8o ^, the amount of heat necessary to carry out the reaction the partial or total combustion of the hot gases is supplied, then after the absence of the unsaturated hydrocarbons desired in each case, the decomposition reaction is immediately frozen in the known manner. . 2. Process nAoh Jlnspruoh 1, 4a4 «raw gtkennieioh-i net that the ratio of the uafesaturated which can be produced from the tu wittfiwitt« coal wafers »is KoIiItWiM β · ΐ * | off e, gate to all of ethylene and JUetyJtns tyfttlt dlf; U tMtiunf · - temperature, this 7 * ftf «rat« v aw «y durob choice to * #» 4 # »Jt- d «r - 22 - ■■. Heiigaee and dee Oxydaiionsetoff.es pending relationship is set. 3 «Procedure according to claim 1 or 2, because it is» kemnseiohnet that the hydrocarbons} fuel gases and the • ■ - Oxydationeetoff are preheated to a temperature of 400 to 6OQ ^{0 C,.} 4 · The method according to one of claims 1 is called 3 »because the components are prior to mixing be one, or the hydrocarbons and heating gases are heated together and the separately preheated oxidizing substance is added to their mixture, or preheating after a previous mixing of the components takes place 5 · Method according to one of claims 1 to 4 »characterized by the fact that the reaction is carried out at a pressure of Qf3 to 20 ata. 6. Procedure according to one of the anesthesia 1 to 4) because you know that the oxidizing substance is carried in such an amount with which one can react the / the respective composition of the introduced misohung corresponding upper. Zündgrenee, raw under homogeneous combustion conditions * 7 * method according to one of claims 1 to 6 »da * by gekennzQrehnet, dft ·· the amount de · la Ausgingfgemisoh Oxidation substances * located on Orund de »In product · - 009 129/164 V. remaining oxygen concentration is regulated in this way » that the oxygen level falls between 0.2 and 0.5 vol. #. 8. Method naoh one of claims 1 "to 7» characterized in that a predominantly "hydrogen and carbon oxide" consisting of the product gas is used as the heating gas of the r.r.ch process Separation of the unsaturated hydrocarbons Gas mixture obtained, whereas pure oxygen is used as the oxidizing substance. 9. Brennvorriohtung for flame enreaction of gas * " mixed" combustible and oxidizing vapors or oases, iro * boi in the - between the l) iffusor distributing the combustible mixture and the combustion chamber - inserted section of narrowed free cross-section of a channel system with smaller and larger flow resistance is designed, in particular for carrying out the method according to one of claims 1 "to 8, characterized in that the free cross-section of the said section is made up of a good heat conductor, two-dimensional by means of a good heat conductor arranged parallel to one another, with spacers» separated, cooled with the combustible mixture Metal-made plates is narrowed in such a way that the ratio of the joints delimited by the plates, smaller flow resistance and the plate cross-sections, falls between 1 and 1? both applied 009829 / 16A6 BATH ORIGINAL loads between the joints in the laminar, in the combustion chamber however, falls into the turbulent Boreicli. 10 The device according to claim 9} characterized in that the distance cooler from the plates delimiting the joints or from plates resting on them, but thinner, in the direction of flow corresponds in places to the joint width! ₍ 7 ^ nutu1cn VLcti ^ r. Eggs formed from separately inserted ribs sinJ, 11. Yorrichturr according to claim 9 or 10, characterized gekonnzciel ru J, let · 1Λ <- Kinälc grösaeren flow resistance d »T in dvn Distanzhrl-iteir ^ PPCN ausfnbildot are. 12. Device according to (inem of claims 9 to 11, characterized in that; t konnroiclVrot, dasa the channels larger Ströniungswidorstanlct, in lic- - cioh to the adjoining plate anpaeeen- Io - oboe flat, the distance holding gate as recessed grooves -, - v si ! .l < l's. Vonichtur. "R ^ ch i-iturn of claims 9 to 13, thereby, vk.un ^ tichnet, that the thickness of the plates between 1.5 and 3 Tsr:> -, II height but between 50 and ^ 200, expedient falls between 70 and IOC! rn. 009822/1646 _bathroom