Catalyst for ammonia synthesis and process for producing the same

专利摘要:
A spherical cerium-activated catalyst for the NH3 synthesis is prepared by: mixing magnetite with (by weight): 2-3.5% of aluminum oxide, 0.8-2% potasium hydroxide, 2-3.5% calcium oxide, 0.1-0.4% magnesium oxide and 0.2-0.5% silica; melting this mixture in a furnace at a temperature of at least 1600 DEG C.; air-cooling the molten mass, removing melted slag; crushing the deslagged mass in a crusher and pulverizing it in a rod-mill; adding in a mixer to the so obtained powder a cerium nitrate solution in quantities to obtain in the final catalyst a metallic cerium concentration of 0.5 to 2.5%; pelletizing the so added powder in a tray pelletizer to obtain a sphere shaped catalyst; drying said catalytic spheres in a furnace 100 DEG -200 DEG C.,and sintering them in an argon atmosphere at a temperature of 1250 DEG -1350 DEG C.
公开号:SU978716A3
申请号:SU802877704
申请日:1980-02-04
公开日:1982-11-30
发明作者:Пассарьелло Аттилио
申请人:Аммониа Казале С.А. (Фирма)；
IPC主号:

专利说明:

(54) CATALYST FOR AMMIAK SYNTHESIS: AND METHOD FOR ITS OBTAINING
This invention relates to an ammonia synthesis catalyst and to an assay process thereof.
A known catalyst for the synthesis of ammonia, containing magnetite and promoters - alumina, calcium, potassium, magnesium and silicon, and cerium metal. The content of cerium in the catalyst is 0,, 5 wt.% 1.
The catalyst has a low activity in the reaction of ammonia synthesis (at 4OO-500 ° C and a space velocity of 161OO-165OO h, the yield of ammonia is 13.5-17.88% by volume).
The closest to the proposed technical essence and the achieved result is a catalyst for the ammonia in ballpoint form with a diameter of 1 - 25 mm, containing magnetite and aluminum oxide, potassium, galyusha and magnesium in the following ratio of components, wt.% :.
Aluminum oxide 2.0-3.5
Oxide of potassium 0,6-1,7
Calcium Oxide 2, O-3,5
Magnesium oxide 0.1-0.4
Magnetite Else
As a binder, catalyst 5 contains bentonite C 2.
The known catalyst has a week “sufficiently high actrvnost. So, you-, the course of ammonia with bulk CKopocTja. 2OOOO and at a pressure of 315 kg / cm at 10 is 12.7% by volume and at 45 ° C is 20.9% by volume.
The purpose of the invention is to increase the activity of the catalyst in the temperature range of 370-450 0.
15 This goal is achieved by the fact that the catalyst for ammonia synthesis in a perforated form with a diameter of 1-25 mm, containing magnetite and alumina, potassium, calcium and magnesium, contains magnetite containing 28% by weight of ferrous oxide, and additionally dioxide, as magnetite. silicon and cerium metal in the following ratio of components, wt.%: Alumina 2.0-3.5 Oxide oxide O 6-1.7 Calcium oxide 2,, 5 Magnesium oxide OD-O, 4 Silicon dioxide 0.2-0 , 5 Cerium. 0.5-2.5 Magnetite, containing 28 wt.% Ferrous oxide. Rest The activity of the proposed catalyst in syn EZE ammonia is increased in comparison with the prototype and is under identical experimental conditions at about 16,4-18,0.%; at 450 ° С 20, .9-23.0 vol.%. At the same time, the catalyst has sufficient heat resistance (its activity after overheating for 1 O h at 600 ° corresponded to the initial one). A known method for producing a catalyst for ammonia synthesis by displacing iron oxide and promoting oxides of aluminum, calcium, potassium, magnesium, silicon dioxide to melt the mixture in the presence of 0.1-0.2 wt.% Powdered graphite, crushing and sieving the melted and cooled pig, reducing catalyst using hydrogen or a nitrogen-hydrogen mixture, treating the reduced catalyst with a solution of cerium nitrate and drying C1. The disadvantages of the method .- obtaining a catalyst with low activity (yield of ammonia 13.5-17.88 vol.%) And the need to introduce an additional recovery process. The closest to the proposed technical essence and the achieved result is a method of obtaining a catalyst for ammonia synthesis by mixing magnetite with 2.0-3.5 wt.% Oxide a; mention 2, O-3.5 wt.% Calcium oxide. , 0.1-O, 4 wt.% Of magnesium oxide and 0.6-1.7 wt.% In terms of the potassium oxide of the potassium compound - potassium carbonate, melting the mixture at 1600 ° C, cooling it with air followed by slag grinding the cooled easplacha in a rod mill, granulation with continuous powder supply, drying at 1OO-2OO ° C and sintering in the atmosphere of argon at 125013 50 C. At the same time, before granulation, added water and bentonite in the amount of 0.258, O wt.% to the catalyst mass 2. mesh 65-120 120-22 O% 20.94 11.60 2 The disadvantage of this method is in the preparation of a catalyst with low activity in the reaction of ammonia in the temperature range of 370-450 ° C (yield of ammonia is 12.7 and 20.9% by volume at a flow rate of the gas stream (Hj / N2 3.1) 2000O, pressure 315 kg / cm 400 and respectively). Objective: to obtain a catalyst for the synthesis of ammonia with higher activity. This pellet is obtained according to the method of producing a catalysts for ammonia sietez by displacing magnetite from 2, O-3.5 wt.% Alumina, 2, O3, 5 wt.% Calcium oxide, 0.1-O, 4 wt.% Magnesium oxide and 0.6–1.7 wt.% in terms of potassium oxide, potassium compound, melting the mixture at 1, cooling it with air, followed by removing the slag, grinding the cooled melt in a rod mill, granulating with continuous powder supply, drying at 100- 200 ° C VI sintering in an argon atmosphere at 1250-1350 ° C, in which as a potassium compound is used Comforting potassium hydroxide, mixing is carried out in the presence of silicon dioxide and an aqueous solution of cerium nitrate in quantity is added to the melt crushed in a rod mill with stirring, providing 0.52.5% by weight of cerium in the catalyst, and the granulation is carried out in a granupor equipped with a plate. Example 1. Raw materials containing, kg: natural magnetite 200; alumina 4.6; potassium hydroxide 2.6; okas, calcium 6,6; magnesium oxide 0.28; dioxide silica 1.44, loaded into the mixer and then melted at 1600 ° C for 1 hour. This mixture contains 61.4% and 28% FeO. The mass obtained by melting, after curing as a result of air cooling in the crucible, is removed from the crucible and, after it has completely cooled, crushed and rubbed into powder in a rod mill. The powder obtained by grinding in a mill has a mass of 5 kg and the following granulometry: 5O 250-270 270-325 6 18.18 44.92 The powder is blown into the BMecYe mixer with a solution of 0.2 kg aeri nitrate. Ce (NOj), in 0.2 kg of air (l, 29% of metallic peri in the final product). After that it is fed to a plate of a granulator, having a diameter of 125 cm and a slope of 60 to the horonaonal plane, on which for a period of time, it turns into pellets that have a diameter of 0.2-0.5 mm and which, as a result of growth, turns into pellets with a diameter of 1.5-2.5, in a very short time, by absorbing essentially the entire mass of rsiyka, which at the moment. load into the granulator. After granulation, the product has bead pellets (1.52, 5 mm in diameter), then it is calcined on an electric spiral for pre-drying at, and then baked in an atmosphere of argon at. A catalyst of the following composition is obtained, wt.%: Aluminum oxide - 2.5 Potassium oxide 0.8 Calcium oxide 3.2 Magnesium oxide O, 13 Silicon dioxide 0.5 Cerium 1.3 Magnetite containing 28 wt.% Ferrous oxide. Other Example 2. 2.8 kg of the catalytic powder obtained as a result of grinding in a rod mill of Example 1 is dispensed into 1 test product with a solution containing 0.2 kg of cerium nitrate and 0.1 g of water (2.3% by weight of cerium metal in the final product ). The sprayed powder is granulated, dried and calcined in accordance with Example 1. The diameter of the particles is maintained in the range of 1.5-2.5 mm. The catalyst obtained is the following sos, tava wt.%: Aluminum oxide 2.5 Potassium oxide 6.8 Calcium oxide 3.2 Mg oxide 0.13 Silicon dioxide 0.5 Cerium.2.3 Magnetite containing 28% by weight of iron oxide Balance Example 3.5 kg of a catalytic powder obtained as a result of grinding in a rod mill according to example 1 is treated with a solution of & In 4 of 1 kg of yery nitrate and 0.2 kg of water (O, 64 wt.% cerium in the final product). After injection, the powder is granulated, dried and calcined in accordance with Example 1. A catalyst of the following composition is obtained, wt.%: Oxide Alkminin -2.5 Potassium Oxide 0.8 Calcium Oxide 3.2 Magnesium Oxide 6.13 Silicon Dioxide .0.5 Cerium0.64 Magnetite containing 28% by weight of oxide zhedeza Else Example 4. Offset 206.56 kg. natural magnetite, 3.68 kg of alumina, 2.1 kg of potassium hydroxide. (4.18 kg of calcium oxide, 0.21 kg of magnesium oxide and 0.57 kg of silicon dioxide, melted, cooled with air, freed from slag, crushed and ground into powder as in Example 1. The ground powder is treated with a solution of cerium nitrate the amount of 0.07 kg in 0.1 kg of water (O, 5 wt.% cerium metal in the final product.) The powder thus treated is granulated, dried and sintered as in Example 1, a catalyst of the following composition is obtained, wt.%: Alumina .2.0 Potassium Oxide 0.6 Calcium Oxide 2.0 Magnesium Oxide, 0.1 Cretly Dioxide - 0.2 Cerium 0.5 Magnetite, with holding 28% by weight of ferrous oxide Else Example 5. Mixed 191.68kg of natural magnetite, kg of aluminum oxide, 5.7 kg of potassium hydroxide, 7.33 kg of calcium oxide, 0.86 kg of magnesium oxide and 1.44 kg of dioxide, weigh Air is removed from the slag, crushed, and ground into powder as in Example 1. The powder obtained in this way on a rod mill is treated in a mixer with 0.38 kg of cerium nitrate in O, 3 kg of water. The processed powder obtained in this way is granulated, dried and sintered as in Example 1. A catalyst of the following composition is obtained, wt.%: Aluminum oxide 3.5 Potassium oxide 1.7 57 Calcium oxide 3.5 Oxum mag 0.4 Silicon dioxide 0, 5 Cerium A2.5. Magnetite containing 28 iaec.% Zheovex otoxi Ostalno The proposed cataluators are tested in ammonia ammonia. The tests of the proposed catalysts and catalyst-41 prototes are carried out as follows. A mixture of f -j + SH obtained by cracking ammonia & after purification or sip-washing of residual ammonia, is compressed in a multi-stage reciprocating compressor and after the final to remove the last traces of water and oil are sent to the ammonia reactor, where the reaction occurs at a constant temperature (+ 1 ° C over the catalyst ). The temperature is regulated by external electric heaters. Preliminarily, the resulting gas, which was removed from the converter, is cooled, atollize the ammonia content and the amount of residual gas is measured.
redgas and 1
13.05
370 17.8 40O 20.5 425s 23.05 450
12.5
370 17.05 400 19.9 425 22.5 450
11.6
370 16.4 400 19.3
425 21.7 450 68 The inlet speed is calculated using the above mentioned straps. The dp catalyst chamber in the ammonia converter is a 20 mm high chamber, the catalyst volume is 5 cm. The catalyst is reduced at 370-500 ° C and 1OO bar. When the catalyst is stabilized, it is subjected to a pressure of 315 bar, 4500 ° C and a volumetric flow rate of stabilization. Stabilization is considered to be 20000 h when it is satisfactory, when two consecutive ana | iza-ammonia give the same result. In activity tests, the catalyst is adjusted to the desired conditions (pressure, temperature, volume velocity). When the conditions stabilize, analyze the ammonia content and measure the gas flow. A comparative characteristic of the activities of the proposed catalyst and the prototype catalyst is presented in the table (test conditions: NW 200OO, P 315 kg / cm, ratio H, ... Nj 3: 1).
9
07671610
Table continuation

权利要求:
Claims (2)
[1]
1. US patent No. 3951862, CL. 252/446, published. 1976.
1. The catalyst for the synthesis of ammonia in ball form with a diameter of 1-25 mm, containing magnetite and aluminum oxides, potassium, calcium and magnesium, with the exception of the fact that, · in order to increase the activity of the catalyst, it contains magnetite as magnetite, containing 28 wt.% iron oxide, and additionally silicon dioxide and metallic cerium in the following ratio of components, wt.%:
Alumina 2.0-3.5 Potassium oxide 0.6-1.7 Calcium oxide 2.0-3.5 Magnesium oxide 0.1-0.4 Silicon dioxide. 0.2-0.5
VNIIIPI
Order 9249/78
20 cerium. , 0.5-2.5
Magnetite containing 28 wt.% Iron oxide
2. A method of producing a catalyst for 25 synthesis of ammonia by mixing magnetite with 2.0-3.5 wt.% Alumina, 2.0-3.5 wt.% Calcium oxide, O, ΙΟ, 4 wt.% Magnesium oxide and 0.6-1.7 wt.% In terms of potassium oxide of compound 30 potassium, melting the mixture at 1600 ° C: cooling it with air, followed by removal of slag, grinding the cooled melt in a core mill, granulating with continuous feeding of 35 powder, drying at 100-200 ° C and sintering in an argon atmosphere at 12501350 ° C, characterized in that, in order to obtain a catalyst with increased activity w as potassium soe40 of the connections are used potassium hydroxide, displacement is carried out in the presence of silicon dioxide and a rod mill for particulate melt is added with stirring an aqueous nitrate solution *.
43 that cerium in an amount that ensures the concentration of metallic cerium in ka—; The catalyst is 0.5-2.5 wt.%, And granulation is carried out in a granulator equipped with a plate.
50 Sources of information taken into account in the examination
[2]
2. US patent No. 4073749, "CL. 252 / 455P, published. 1978 (prototype)
Subscription
Circulation 583
Branch of PPP 'Patent', Uzhhorod, st. Project, 4

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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IT47920/79A|IT1114730B|1979-02-07|1979-02-07|SPHERICAL CATALYST ACTIVATED WITH CERIUM FOR THE SUMMARY OF AMMONIA AND THE PROCEDURE FOR ITS PRODUCTION|

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