DE1012413B - Process for supplying heat using a shot as a heat carrier to a hydroforming zone - Google Patents

Description

The invention relates to improvements in the supply of heat to endothermic processes, such as B. in hydroforming, to maintain the thermal balance in the process, and in particular to the type of process in the presence of a fluidized bed Catalyst is carried out, which is contaminated in the process and, as a result, under subsequent Release of heat must be regenerated. The invention makes it possible this heat to support the reaction that can consist in the hydroforming of heavy gasoline, hold back.

The hydroforming of advertising spirit for production an improved octane product boiling in the gasoline range is one in the industry usual procedure. First you work with a resting bed made of catalytic material. During the working phase of this type of process, the temperature drop in the reaction vessel is during the Hydroforming is very high, and it has been common to use a plurality of reaction vessels that are in Row worked and were reheated in between.

In recent times, numerous studies have been carried out into the technique of working with whirled up powdery catalyst to adapt the hydroforming of heavy gasoline. Such a thing The method has the advantage over the method working with quiescent beds that it is continuous can be performed, has adaptability, a uniform temperature in the catalyst layer has a larger exposed catalyst surface for contact with the Provides reaction vapors and otherwise works more satisfactorily than a quiescent pouring using procedures. In a two-vessel system in which hydroforming is easy can be carried out using fluidized bed technology, hydroforming perform in a vessel in the presence of the fluidized catalyst bed, and that in the hydroforming reactor Contaminated catalyst can be withdrawn from the reaction vessel continuously or at intervals and passed into the regeneration zone in which it is regenerated and from which it is returned to the reaction zone. In which Working with quiescent embankments it was of course necessary to start the productive phase of the hydroforming process to interrupt and the contaminated catalyst with a regeneration gas to treat to reactivate it.

Hydroforming is a process in which raw heavy gasoline, cracked heavy gasoline, is a process for adding heat
using a shot

as a heat transfer medium
to a hydroforming zone

Applicant:

Esso Research and Engineering Company, Elizabeth, N.J. (V. St. A.)

Representative: Dr. W. Beil, lawyer,
Frankfurt / M.-Höchst, Antoniterstr. 36

Claimed priority:
V. St. v. America June 21, 1954

2

synthetic heavy gasoline or a mixture of these materials is brought into contact with a solid catalytic material at elevated temperatures and pressures in the presence of hydrogen. The process is carried out to avoid consumption of hydrogen and there is usually a net production of hydrogen. During hydroforming, the reaction conditions are a temperature in the reaction zone in the range between about 400 and 565 °, a pressure between about 3.5 and 70 kg / cm ² , and per oil feed in the reaction zone, a circulating gas is used in an amount between about 35 and 125 m ³ with a hydrogen concentration between about 50 and 90% used.

For the hydroforming of heavy gasoline

Catalysts used include metals such as platinum or palladium on a suitable support as well as the oxides and sulphides of certain other metals, in particular of molybdenum, chromium, vanadium and tungsten, also on a carrier. A good The carrier for these materials is an active alumina form with an adsorptive or large surface must have. A satisfactory carrier is an alumina which has a major portion of the ^ alumina form contains.

The invention is primarily directed to an effective means of supplying heat to the hydroforming zone. So far one has planned

709 58a / 253

beaten, this by preheating the feed oil and the hydrogen-containing circulating gas as well as through To achieve transfer of hot catalyst from the regenerator into the reaction zone. Here certain disadvantages become noticeable. The amount of heat generated by preheating the feed oil can be fed is sharply limited, since this feed material is inevitably an essential Contains a lot of naphthenes, which decompose to products made up of carbon and dry Gas exist when the loading material is heated to a temperature above about 455 to 540 °. In terms of of the circulating gas is to be said that this material from the product recovery system with a temperature of about 38 ° is obtained. This material to a temperature of 590 to 760 ° heating is an expensive and undesirable operation. It also occurs with the heavier ones Hydrocarbon components of the circulating gas decompose when heated to 650 ° or above Carbon and dry gas existing products with consequent loss of valuable Products. Regarding the catalyst it can be said that it does not do so at a temperature above 620 ° can be regenerated without damaging the catalyst; as a result, the previous Functioning cooling devices in the regeneration zone applied to excess To remove heat from the catalyst and from the system. When hydroforming according to the fluidized bed technology In contrast to the kataly ti, which was carried out in the same way, one cannot see large cracks Amounts of heat from the regenerator to the reaction zone using a high rate of catalyst circulation transfer, as it is possible with cracking, where z. B. 10 to 20 parts by weight hot catalyst per part by weight of oil used in the cracking zone can be used. Such catalyst circulation ratios can occur during hydroforming heavy petrol should not be used, as catalyst-oil ratios above about 1: 1 Excessive carbon formation and product distributions in the yield result from economic Are disadvantageous. In addition, shot is already used as a heat exchanger in fluidized bed processes used. The catalyst and grist were in the same way between the reaction zone and the regeneration zone circulated and each subjected to the same treatment.

According to the invention, the heat released during regeneration is transported into the hydroforming zone by means of a circulating heat transfer material or shot, such as mullite. Of course, other heat transfer materials such as sand, silica gel, and various metals can also be used. However, the shot is preferably composed of an inert substance with a larger average particle size than the catalyst and a higher density of debris and fluidized bed than the catalyst. It must also be wear and tear resistant and able to withstand physical crushing and shattering when used in the form of a dense turbulent fluidized bed. When using a heat transfer material which is larger and denser than the catalyst, the residence of the inert material in the reaction zone is very short and the volume of the reaction zone required for a given degree of reaction becomes little due to the presence of the small amount of heat transfer material impaired. The invention improves upon prior practice and suggestion in that it provides a means by which the weight ratio of shot to catalyst in the circulating stream can be changed, thereby changing the rate at which heat passes through the heat transfer material is fed to the reaction zone. This adaptability of the heat transfer to the reaction vessel is very desirable in hydroforming in order to enable a wide range of process conditions to be used in the plant so that different degrees of conversion can be achieved. Furthermore, many heavy fuels require stricter conditions during their hydroforming and must be treated with the addition of larger amounts of heat to the reaction zone. The invention comprises devices with which any desired amount of heat can be introduced into the reaction zone by changing the rate of feed of the meal to the reaction zone. As already indicated, the shot material preferred in the method according to the invention consists of mullite, a material of the formula 2 SiO ₂ · 3 Al ₂ O ₃ , which is preferably used in the form of small spheres with an average particle size in the range between 300 and 700 μ. This material has a particle density of about 3.12 kg / l and a bulk density of about 1.84 kg / l. In contrast, the catalyst normally used in hydroforming has a much smaller particle size and density. A typical hydroforming catalyst containing about 10 percent by weight molybdenum oxide and 90 percent by weight alumina has an average particle size of about 60 to 80 / t, a particle density of. 0.96 to 1.76 kg / l and a bulk density of about 0.63 to 0.88 kg / l.

According to the previous proposals, the shot and the catalyst were in a common stream out of the reaction zone into the regeneration zone and, after regeneration, back to the reaction zone. An increase in the concentration of the shot resulted from the tendency of the heavy shot particles, to settle through the less dense fluidized bed in the reaction zone. As a result This tendency towards concentration can change the ratio of catalyst to grist in such a Circulating flow can be increased further by passing a mixture through a tube with a gradually increasing reducing cross-section leads.

According to the invention, a device is provided by which the shot concentration still further increases and the weight ratio of grist to catalyst in the circulating stream of solid particles can be easily regulated.

The invention also contrasts an improvement the previous practice and the previous proposals by providing devices to prevent the separation of grist and catalyst at the bottom of the reaction zone and in the transport system for the solid particles, if an interruption in the circulation to the regeneration zone occurs. In previous practice there was an interruption the circulation of solid particles caused by adverse conditions, pressure fluctuations in the system or failure of mechanical system parts has been caused, usually an extraordinary one high shot concentration at the bottom of the

Reaction vessel and in the transport system for the solid particles up to the circulation control valve for Episode. This mass, which consists of almost pure shot, is difficult to move. According to the invention however, a mixture of grist and catalyst will continuously return from the bottom of the reaction vessel passed to the reaction zone. The valve controlling the circulation is located near this recirculated Electricity, and an interruption of the

is recovered, passed through the lines R and R ₁ to the shaft 3, which, as shown, is arranged at the bottom of the vessel 1. This gas flows up through the shaft 3 into the fluidized bed C. Further circulating gas is admitted through the line R _v. Under the known conditions of temperature, pressure, the amount of circulating gas and the residence time, the desired hydroforming takes place in the fluidized bed C ₁ and the vaporous

The solid particles circulate to the regenerator and the product emerges from the fluidized bed C and practically no accumulation of pure meal flows through between L and the upper end of the in the transport system. According to the invention, the hydroforming of the main part of the entrained solid particles is carried out, which falls into the fluidized bed C using the fluidized bed technique from the vaporous material by supplying heat to the reaction vessel. Before the crude product zone is carried out by means of devices that are withdrawn from the reaction vessel, it is usually more effective and cheaper than those previously proposed and desirable, it is significantly improved by one or more gas-blown, using a solid separator Cy or Cyklone too Hydroforming plant which operates with a fluidized bed in order to separate fine particles from the products from a catalyst and which consists of a reaction zone and a regeneration zone, consisting of a reaction zone and a regeneration zone, in which fine particles pass through one or more downpipes d into the Thermal equilibrium is kept by returning the fluidized bed. The product exits at the top of the reaction vessel through conduit 4 and regenerator to the reaction zone by means of a transfer rate of heat is passed to a product recovery plant, in running heat transfer material that circulates at a rate that allows it to obtain the desired hydroformats the heat requirement and further to the recovery of a circulating gas for the

nits in the reaction zone, regulated.

According to the invention a device is used by which the speed of heat transfer from the regeneration zone into the reaction zone is regulated by the fact that the weight ratio controls from grist to catalyst in the circulating stream of solid particles.

In addition, the device is for circulating

Reuse in the process carried out in reaction vessel 1 in customary devices is treated.

As already stated, contaminants form on the catalyst during hydroforming Deposits that affect its effectiveness. These deposits are of their nature after primarily carbonaceous, and if that

an inert heat transfer material or shot 35 feed material contains a substantial amount of sulfur

from a regeneration zone to a reaction zone in some form, at least a portion is suitable, both zones being made up of fluidized beds
Contain catalyst, so that in the stream of zir

cumulating solid particles have a weight ratio

oxidative regeneration is subjected to the removal of the contaminating deposits, whereby the catalyst is cleaned and its effective

this sulfur is also deposited on the catalyst. In order to reactivate and regenerate the catalyst, it is removed from the reaction zone Grist is present to catalyst, which is pulled up to 7 or 40 and transported to a second vessel, is more, preferably 2 to 10. which contains a regeneration zone in which he is a

Devices are used through which the complete separation of the shot and catalyst is prevented at the bottom of the reaction vessel,

when the circulation of solids to the regenerator is restored from time to time. To this end, a interrupted for some reason. Mixture of catalyst and heat transfer

Tn the drawings in Fig. 1 is the installation of a material from the bottom of the shaft 3 through the Leiaus two. The existing hydroforming device 5 is withdrawn from the vessels, which, as shown, shows a U-bend system that contains a reaction zone and one, and then upwards as a riser 7 into the regeneration zone as well as transport lines, leading 50 fluidized bed C of the reaction vessel 1. Mainly which connect the two vessels, and partly due to the fact that the heat transfer device for catalyst and shot carrying material or the shot is denser and in to and from the zones and further a device averaging larger than the catalyst, this has to increase and regulation of the weight ratio heat transfer material or the shot the niss of shot to catalyst in the circumferential 55 tendency to present on the lower wall of the U-shaped stream; in Fig. 2 is a partial view of a bent part of the conduit 5 to concentrate. Of the

On the other hand, the less dense and average smaller catalyst collects near the upper wall of the U-bend in line 5 and is released into the reaction vessel 1 by a lifting gas that is admitted through lines a, b, c and d into line 5 located fluidized bed C transported. The shot, on the other hand, which collects on the lower wall of the U-bend, is withdrawn from there through a line 8 provided with gasoline, with a content of 30 to 40 percent by volume 65, which is filled with naphthenes, which is essentially in the area between the U-bend is in connection, and is boiling in about 95 and 205 °, is through the line 2 a gas, z. B-. Air passed through a main into the reaction vessel. Simultaneously, bypass line 8 α is carried into regenerator 6 at a point at or near the flow of gas (ie, a _{gas containing H 2} ) introduced into a production recovery system (not shown) at the lower end of a riser pipe 9 (not shown). A majority

Modification of the system described in Fig. 1 shown.

In the drawings, like reference characters refer to like parts.

In Fig. 1, 1 represents a reaction vessel comprising a fluidized bed of hydroforming catalyst C and shot or heat transfer material J? contains. Preheated oil, such as unprocessed heavy

of gas inlet pipes are, as shown, with the shot, as stated, spaced between the two joints arranged to do additional uptake at a much greater rate than to supply vortex or lifting gas. Since the ab- the catalyst.

drawn meal and catalyst in line 8 and In Fig. 2 is a modification of the shown in Fig. 1

the ascending pipe 7 adsorbed and / or enclosed 5 showed exhaust device shown. It should be noted that in this modification the U-bend in Line 8 does not open directly into the returning U-bend in line 5, as shown in FIG. 1

Containing hydrocarbons and hydrogen, it is preferable to the influence of this mixture Cleaning or stripping gas, such as. B. Steam, subject to the hydrocarbons and the

is posed. As shown in FIG. 2, one section is dous

Remove steam. This can be done in an outside io bottom of the U-bend in the line 5 by a

dhbh Pl 1 d V

the system located (not shown) wipers. The separation of the catalyst from the shot in the U-bend of the line 5 can be controlled by adjusting the aeration speed through the feeds a, b and c in the U-bend. ¹ S The separation between the catalyst and the shot in the U-bend is incomplete and a substantial amount of catalyst is carried into the regenerator with the shot. However, a substantial part of the catalyst introduced into line 5 is returned to the reaction vessel through riser 7, so that the concentration of the catalyst in regenerator 6 is much lower than in reactor 1. The concentration of the meal in regenerator 6 is much higher than that in reactor 1, and as shown below, this mixture of catalyst and grist is returned to the reactor after treatment by air. Thieves-

replaced perforated plate 14, under which a device 13 is provided for admitting gas. The amount of supplied through line 13 Gases can be adjusted so that the pressure drop across the openings of the plate 14 changes and through this measure achieves a further separation of the heavier shot particles from the catalyst becomes, since the lighter catalyst ticks do not, «, go. have a greater tendency to settle through the openings than the shot. This arrangement has the λλ-other advantage of the even distribution of the ventilation gas over a wide section of the bottom of the U-bend, thereby making the U-bend work is improved.

It should be noted that the U-bend in the line 5 and the riser 7 allows a continuous return of the mixture consisting of shot and catalyst back to the reactor when the control valve V is in the U-bend

conditions are now set so that the
Catalyst circulation speed from the regenerator 3 ° line 8 is closed. This is then particularly advantageous for about 1 part by weight of catalyst per reactor, if it is desired to reduce the circulation of the

Interrupting solids to the regenerator for any reason. In this arrangement there are none Settings of the aeration in the transport system of the solid particles when the circulation of the solid particles is resumed to the regenerator, as the

Part by weight of oil used in the reactor, but the shot circulation speed can be 2 to 10 parts by weight of grist per part by weight of the oil fed to the reactor.

In the case of the regenerator 6, secondary air can be supplied through the inlet pipes 10 and 10 α. A dense fluidized bed C _{1 is} formed from the mixture of solid particles in the regenerator 6 and extends from a grid or sieve G at the bottom of the regenerator to the upper end L _{1 of} the dense phase. Under the known conditions of temperature, pressure and residence time, the deposits formed on the catalyst and the grist are removed

consumed by combustion, and the exhaust gases enter 45 carbonaceous material, e.g. B. coal, applied from the fluidized bed C ₁ and flow through a be,
separation zone located between L ₁ and the upper end of the regenerator. \ ¥ The ones from the
Exhaust gases from the regenerator forced through
to flow one or more cyclone separators Cy , 5 °
in which the entrained fine particles are separated
which are returned through the downpipes (I ₁ into the fluidized bed C _1. The exhaust gases produced during the regeneration are discharged from the regenerator

withdrawn through line 11 and 55 percent molybdenum oxide and 90 percent by weight clay recovery of their chemical or heat content to the earth consisted at 482 ° and at a pressure of. Used in the present system or in others, 14 kg / cm ^{2 is} treated while 86 m ^{3 of} circulating gas are treated with plants using conventional (not shown) a hydrogen content of 55% per hl of the oil in plants. The treated solids were introduced into the reaction zone. The catalyst particles are drawn off from the regenerator through a downpipe 6 ° had an average particle size of 20 12 and the fluidized bed C in the reactor 1 to 80 μ. The superficial linear velocity of the fluidizing gas in the reaction zone at a point near the top was 12.2 cm per layer of C supplied to allow the second. The ratio of catalyst to oil meal settles through the fluidized bed and the input into the reaction zone was 0.9 kg of Katadarin taking place endothermic reaction heat 65 per kg of oil. The preheating temperature of the feed. The shot settles quickly through the kata oil was 504 °, that of the circulating gas was 565 °. A gelator fluidized bed C in reactor 1 due to its much mixing of grist and catalyst was the larger average particle size. Since the reaction zone fed, which had a temperature of about 538 ° solids circulated from the reactor 6 and to the reactor 6 and about 7 kg of meal per kg of catastrophic mixture has a high concentration of meal, the 7o lysator was running.

Shot concentration in the U-bend in line 5 essentially unchanged during the whole time stayed.

The present invention has been described with reference to a HydiOformierungsverfahren, however, it can also be used in conjunction with other methods, e.g. B. the coking of heavy Petroleum, carbonization and / or gasification of

example

An unprocessed heavy gasoline that boils in the range between 93 and 176 °, 30 to 40 percent by volume Contains naphthenes and has an octane number of 50, was a »s in the presence of a fluidized bed Hydroforming catalyst, which consists of 10 weight

G T

A hydroformat with an octane number of 95 was in 80% yield of liquid product obtain.

Catalysts other than molybdenum oxide and alumina can also be used, including metals such as platinum or palladium on alumina or other support. Next, a metal oxide, e.g. B. chromium oxide, can be used as an active ingredient for the hydroforming catalyst. The temperature in the reaction zone can vary between 465 and 565 °, the pressure can vary between 7 and 35 kg / cm ² , the amount of circulating gas that is fed to the reaction zone and contains 60 to 75% hydrogen can be between 9 and 107 m ³ per hl of oil, and the catalyst-oil ratio can be between 0.5 and 1.1 kg of catalyst per kg of oil. The preheating temperature of the oil can be between 315 and 510 ° and the preheating temperature of the circulating gas can be between 535 and 760 °. It is also possible to use a large number of materials, such as e.g. B. materials that contain 0.5 or more percent by weight of sulfur, materials that contain substantial amounts of olefinic hydrocarbons, and materials that contain only 15% naphthenes and the remainder consists of paraffinic hydrocarbons, to hydroform. The method according to the invention is particularly suitable for the treatment of sulfur-containing materials which are produced using a noble metal catalyst, e.g. B. platinum, cannot be effectively treated. An essential feature of the present invention is its applicability for hydroforming heavy gasoline using relatively low circulating gas velocities, as explained in the previous example, the circulating gas being heated to a temperature of only about 538 ° at the same time, whereby the decomposition of the hydrocarbons in the Avoided recirculation oil and the heating of the recycle gas and the mixed oil used in. A single system is enabled, and no separate heating devices for the oil and the recycle gas are required in which the recycle gas to temperatures on the order of z. B. 760 ° must be heated, which is required when not using hot shot.

Claims (5)

Patent claims: 1. Method of supplying heat using shot as a heat exchanger to a hydroforming zone which is located in a system consisting of a hydroforming zone with catalyst fluidized bed, a regeneration zone with catalyst fluidized bed and There are connecting lines between the hydroforming zone and the regeneration zone, characterized in that the shot and the catalyst by means of an upward flowing, gaseous material in the hydroforming fluidized, the fluidized Shot and catalyst nadh down through a zone of reduced cross-section at the bottom of the Hydroforming zone leads, wherein the ratio of red to catalyst is increased, the resulting mixture of shot and catalyst from the bottom of the zone of reduced cross-section withdraws into a first transport line, the mixture first downwards and then upwards a U-shaped tube with reverse flow direction in an upper part of the Hydroforming zone leads, with a first mixture enriched in grist being lowest Point of the pipe part changing the direction of movement collects and a second, of shot poor mixture formed above the mixture at the point of change in flow direction is, the first mixture is withdrawn nadh down into a second transport line, in the regeneration zone leads, subjected to an oxidative regeneration and as a highly heated mixture of shot and Recirculates catalyst in the hydroforming zone, and a higher one in the regeneration zone Grist to catalyst ratio maintained than in the hydroforming zone. 2. The method according to claim 1, characterized in that a fluidizing gas at the lowest point the change in the direction of flow in the first transport line while increasing the ratio is introduced from meal to catalyst in said first mixture. 3. The method according to claim 1, characterized in that the shot volume in the hydroforming zone is about 2 to 3 percent by volume entire layer consisting of catalyst and shot. 4. The method according to claim 1, characterized in that the ratio of shot to Catalyst, in the regeneration zone and the line through which the catalyst from the regenerator is passed into the reaction vessel, about 2 to 10 parts by weight of grist per part of catalyst. 5. The method according to claim 1, characterized in that a stagnation of the solid flows between the hydroforming zone and the regeneration zone, which is an interruption of this Current is caused by means of which all of the hydroforming zone is eliminated withdrawn catalyst and grist are returned directly to the hydroforming zone until the flow has ceased will. Considered publications:
U.S. Patent No. 2,400,176. 1 sheet of drawings © 709 588/253 7.57