DD244353A1 - METHOD FOR CONTROLLING REFORMING AND AROMATING PLANTS - Google Patents

Abstract

The invention relates to a method by means of which it is possible to reactors, which for the conversion of hydrocarbons, such as hydroreforming or for the production of aromatic hydrocarbons such. As benzene, toluene, xylene and C9 aromatics from saturated or unsaturated gasoline are suitable to operate in the direction of a high Gesamtaromatenausbeute and Fluessigausbeute, as well as a high octane number of the final product. It does not matter whether the reforming and aromatisation plant consisting of at least 3 reactors and 3 inlet heaters works with a fixed or moving bed. With the aid of the Reformat or Aromatisatqualitaet leaving the plant, the amount and mathematical algorithms is a control of the desired total aromatics yield over the reactor inlet temperatures regardless of the input quality based on the boiling range in which such systems work. The invention can be used particularly advantageously where, owing to the particular market situation or systems operated upstream, there are notable fluctuations with regard to the quantity and boiling point of the feedstock or the like. Reactors is coming.

Description

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Field of application of the invention

The invention relates to a method by which it is possible, reactors which for the conversion of hydrocarbons, such as hydroreforming or for the production of aromatic hydrocarbons z. As benzene, toluene and xylene (ortho, meta or para) and C ₉ ⁺ aromatics from saturated or unsaturated (pyrolysis and cracking gas) hydrocarbons from thermal or catalytic cracking serve, effectively both in the direction of a high aromatics and liquid yield, as also to operate a high octane number of the final product.

Particularly advantageous, the invention can be used there, where due to the particular market situation or by the manner of operation of connected systems there are noticeable fluctuations in the amount and Siedelage of the feedstock o.g. Reactors is coming.

Characteristic of the known technical solutions

There are many processes worldwide for the production of high-octane reformates or aromatics with the aid of catalytic reforming plants.

The background is once in the growing demand for certain aromatics such. As gasoline on the world market and thus justified in the high economic importance of these products.

This is also true of the growing demand for high octane gasolines due to efficiency improvements by increasing the compression ratio of internal combustion engines. -

On the other hand, the multitude of processes results from the effort to constantly increase the yield with decreasing consumption of energy and auxiliary materials, in order ultimately to increase the overall economy of the process. In recent years, so-called catalytic low-pressure regeneration processes with moving catalyst bed have prevailed for the production of aromatics and high-octane reformates (CCR or aromatization process).

These processes work in several stages and with continuous catalyst regeneration.

As an example, here are DE 2803284, DE 2819753, DE 2759367 and US Pat. 4167473 mentioned as patents for these methods.

The processes mentioned achieve high aromatics yields and high selectivity due to the low pressure, the specific catalyst types and the frequent regeneration of the catalyst.

The reaction conditions are at 673-873K reaction temperature, pressures between 4-15bar and hydrogen carbon ratios between 1: 1 to 10: 1. As input product, a naphtha in the boiling range between 333-478 K is usually used.

The achievable Aromatenausbeuten are not specified in the rule.

The reaction conditions show that they leave a great deal of latitude in terms of increasing such processes towards an effective yield. The main disturbances of said processes are mainly to be found in the varying feed product quality, which it is necessary to track the most easily influenced reaction conditions reaction.

For this purpose, appropriate criteria can be found.

In the patent research and in the relevant literature conventional arrangements were found, which only allow the constancy of the reaction conditions once set (quantity, pressure and temperatures), but do not independently act in the direction of a high yield.

Methods are known for such reaction systems, where it is attempted with the help of a mathematical model, the complicated processes that take place in the individual reactors to interpret newly to be built facilities according to or adapt to the changed conditions in reconstructions. The disadvantage of this method is the high manual effort in the preparation of such models and since the ongoing reaction mechanism in reforming and aromatization is not known exactly, in a constant tracking of such models in order to maintain their validity.

From the literature, however, concepts for controlling the octane number of reforming plants which are used exclusively for the production of high-octane fuel, such as. It is, of course, not transferable to installations which have a variable production program (aromatics and fuels) in varying proportions to have.

Object of the invention

The inventive method has the goal over known solutions by means of control devices and mathematical algorithms a reforming or aromatization plant by specifying a Reaktortstemperaturingangsprof ils to control so that the most economical production of aromatics or a particular individual aromatic and fuel is ensured and that fluctuations in the In addition, conditions for the liquid yield, aromatics yield, etc. are to be compensated be respected. The flexibility of the system should be guaranteed or improved by the method according to the invention, i. H. the conversion from one target product to another should be quick and easy.

At the same time, the heating capacity is correspondingly utilized to full capacity and, in connection therewith, capacity and energy losses are reduced.

Explanation of the essence of the invention

The invention has for its object to develop a method which allows operating from at least 3 reactors and 3 input heaters reforming and aromatization plant to operate according to more effective criteria than is possible with hitherto conventional means

 This has the following advantages over conventional driving:

- Keep the total aromatics yield or the amount of a particular individual aromatic at a given level with variations in the EP composition and gradual catalyst aging.

- Utilization of the capacity reserves of the individual preheaters or energy savings by adjusting the corresponding rows of these reactor inlet temperatures.

The solution according to the invention was based on the knowledge that it is compatible with conventional methods, which represent the state of the art, i. Maintaining a specific temperature profile, irrespective of the input product composition or octane control, is not possible to cope with requirements that are consistent with high overall aromatics yield or high yield of individual aromatics with high liquid yield. Similarly, an effective change between two different driving styles is possible only with losses.

It was therefore sought after means and ways to meet this requirement.

The problem to be solved by the process according to the invention is to produce a given total aromatics amount or a desired single aromatics with simultaneously high liquid yield, the influence of the input product fluctuations and the catalyst aging being eliminated by a reactor temperature input profile subordinate to the control target.

The following characteristic values are suitable for controlling the process:

1. Aromantenkennzahl

K _A = AA-FA -FA liquid yield (in% by weight) on feedstock

-AA aromatics yield (in% wt. on feedstock

- K _A aromatics index where: 'N

AA = FA- Σ a,

.A; - individual aromatic fraction (% by weight) in the reformate or flavoring used for the

Aromatenabtrennung is provided.

N- number of individual aromatics intended for aromatics separation. The characteristic Ka is used to characterize the total aromatics yield in the range 2000-5000. p / \ - ^m A IQ "-ιτιε- MassenstromdesEinsatzproduktes for the reforming or aromatization

rh _E -m _A mass flow reformate or flavor

2.VK key figure

K _VK = NA-FA-NA non-aromatic yield (in% by weight) based on feedstock

NA = FA-AA

By the aromatic yield AA, the proportion of aromatics is detected, which is largely separated in a downstream of the reactor distillation and / or extraction block from the reformate or flavoring.

The VK metric characterizes the proportion of reformate or flavor that is mixed into the fuel. It is in the range 1000-5500.

The key figures K _A and K _V k or a combination of both Κχ = PiKa + P2KVK combination key Pi, P ₂ - weighting factors can be determined by a specific reactor temperature incidence profile of the form

Tri> Tr ₂ > T _R3 > T _R4 or

Tri <Tr ₂ <T _R3 <T _R4 or

Tri <Tr ₂ <Tr ₃ > Tr ₄ or

Tri> Tr ₂ <T _R3> T or _R4

Tri <Tr ₂ > Tr ₃ <Tr ₄

be used for the desired control target, wherein

T _R1 = inlet temperature reactor 1

Tr ₂ = inlet temperature reactor 2

T _B3 = inlet temperature reactor 3

Tr ₄ = inlet temperature reactor 4 in a 4 reactor circuit mean.

embodiment

The invention will be explained in more detail with reference to an example.

Fig. 1 shows the process scheme of an aromatics production plant with the means for process control.

The explanation of the method according to the invention will be made with reference to FIG. 1 and Table 1 and 2. At the entrance of the reforming and aromatization plant a feed mixture according to Table 1 and 2 is used. In Tab. 1 and 2, liquid yields FA, aromatic and non-aromatic yields AA and NA, aromatic key figures K _A , VK key figures K _V are combined to form the combination key figures K _x with the associated temperature profiles for different operating modes with different feed products.

The realized temperature profile T _Ri has in the test products ₁ , 2, 3 of Tab. 2 and in VP 1, _{2, 3} , ₄ of Tab. 1 the form Tri <Tr ₂ <T _R3 <Tr ₄ , on the other hand in the test points 5 and 6 of Table 1 and in the experimental points 4,5,6 of Table 2 the form Tr ₁ <T _R2 <T _R3 > T _R4 .

The starting material A is a light middle benzene mixture, B is a Leichtmittelbenzingemisch with increased middle benzine content and in the feedstock C, the middle gasoline content is further increased

 The method according to the invention works as follows:

By the Eingangsmengenmeßfühler 13 of the input flow EP is detected.

Simultaneously, the Aromisatmengenstrom AF, which comes from the heaters 1,2,3 and 4 and the reactors 5,6,7 and 8 and determines the Aromisatzusammensetzung using the Ausgangsanalysemeßfühlers 15 via the Ausgangsmengenmeßfühler 14.

With the help of this information and the previously executed mathematical algorithms is from Kennwertfalkulator 20, the liquid yield FA, the aromatic and non-aromatic Ausaoute Aa and NAa, the aromatics and V | <-K _A K and K _v <. Finally, the weighted combination number K _x calculated. These key figures are determined in the presence of a stationary system status (Tr ,, Pr and EP - konst). The characteristic values determined in this way enter the control and limit monitoring calculator 21.

This contains the last calculated values for the key figures Ka, Kyi <or. K _x stored, as well as limits on the yields FA and AA.

Furthermore, it is possible to provide in the control and limit monitoring calculator 21 also technological limitations such as reactor inlet temperatures and valve opening degrees.

In the further explanation of the application, it is assumed that the aromatic number Ka should be as high as possible, the following conditions being met: FA = 76%, AA = 48%.

In Table 2, VP1, the boundary conditions are met and a K _A , = 4158 is reached. The conversion to the product A gives in the set regime an aromatics index of K _Az = 3648, whereby the boundary conditions are met. Since Ka ₂ <K _A , is increased by the control and Grenzwertüberwachungskalkulator 21 via the adjusting devices 17,18 and 19, the Heizmittelzufuhr to the preheaters 2,3 and 4, the T _R , the reactors 6,7 and 8 raised and the experimental point 3 Table 2 is set. There is Ka ₃ > Ka ₂ .

When driving in accordance with VP4 Table 2, the boundary condition for the aromatics yield is violated during product conversion (s.VP5Tab.2), there is also a sharp decrease in the characteristic K _A. When changing the driving mode according to VP6, the boundary condition is met again and the K _{A is} increased. Table 1 shows how the characteristics change when the same reactor inlet temperatures T _{Ri are maintained} after changing the feed composition

 Losses in plant capacity and yield are unavoidable.

Table 1

VP EP g ^ actor ^ | ntr ^ _tstemp ( _Z ) FA AA

^K VK

1 B 773 2 786 803 807 76.0 25.0 51.0 3876 1940 2906 ir 2 A 773 786 803 807 75.0 26.0 49.0 3675 1950 2812 3 C 773 785 805 808 78.0 28.0 53.0 4134 1950 3042 4 A 773 785 805 808 76.5 27.5 49.0 3748 2104 2926 5 A 785 793 815 788 78.0 31.0 47.0 3666 2418 3042 6 B 785 793 815 788 80.0 V 31.0 49.0 3920 2480 3200 Tabe lie     , ·

VP EP reactor inlet temp. (K) PA NA R1 R2 R3 R4 AA

1 C 773 782 800 804 2 A. 773 782 800 804 3 A 773 785 803 806 4 B 773 783 801 790 5 A 773 783 801 790 6 A. 785 793 815 786

230 54.0 4158 1771 2964

76.0 28.0 48.0 3648 2128 2888

78.0 24.0 54.0 '4212 1872 3042

82.0 32.0 50.0 4100 2624 3362

80.0 33.0 47.0 3760 2640 3200

80.0 .30.0 80.0 4000 2400 -3200

Claims (1)

- 1 - £ fV * 393 Invention claim: Process for the control of reforming and aromatization reactors, characterized in that predetermined yields of total aromatics or individual aromatics and / or carburetor fuel components are achieved, in which the characteristics characterizing these yields K _A = AA · FA aromatics index from 2000 to 5000. Kvk = NA FA VK index from 1000 to 5500 K _x = 1 · K _A + 2Kvk Combination ratio from 1000 to 5500 be controlled by adjusting the reactor inlet temperatures T _Ri , wherein the inlet temperature profile over the reactors is constant, rising, or formed with one or more maxima.