Production of a solid chemical product

Abstract

Method for solidifying a chemical product (10) which is in melt form, comprising the following steps: subjecting a first stream (10a) of said chemical product to a prilling stage, with production of prills (12) of varying diameter; feeding said prills (12) to a screening device, which separates them according to their diameter into at least a first fraction (13) and a second fraction (14), the average diameter of the prills of said first fraction (13) being smaller than the average diameter of the prills of said second fraction (14); subjecting a second stream (10b) of said chemical product and the first fraction (13) of prills to a granulation stage, with the production of granules (16).

Claims

1. A method for solidifying a chemical product which is in melt form, comprising the following steps: subjecting a first stream of said chemical product to a prilling stage, with production of prills of varying diameter; feeding said prills to a screening device, which separates them according to their diameter into at least a first fraction and a second fraction, the average diameter of the prills of said first fraction being smaller than the average diameter of the prills of said second fraction; subjecting a second stream of said chemical product to a granulation stage and feeding to said stage the first fraction of prills, said prills acting as seeds for the granulation, producing granules; and wherein said second fraction is exported and sent to storage.

2. The method according to claim 1, wherein the prills of said first fraction have an average diameter not greater than 1.7 mm.

3. The method according to claim 1, wherein said granulation stage is performed in a fluid bed fed with air.

4. The method according to claim 1, wherein said chemical product is urea.

5. A solidification section for a chemical product which is in melt form, comprising at least: a prilling tower, which receives a first stream of said chemical product, producing prills of varying diameter; a screening device, which separates said prills according to their diameter into at least a first fraction and a second fraction, the average diameter of the prills of said first fraction being smaller than the average diameter of the prills of said second fraction; a granulator, which receives a second stream of said chemical product, producing granules; a feeding line for feeding said first fraction of prills to the granulator, said prills acting as seeds for the granulation; a line for exporting and storing said second fraction of prills.

6. A method for revamping a solidification section for a chemical product which is in melt form, comprising at least: a prilling tower, which receives a first stream of said chemical product, producing prills of varying diameter; a granulator, which receives a second stream of said chemical product, producing granules; a feeding line for feeding said prills to the granulator; wherein it comprises at least the following operations: a screening device is installed downstream of the prilling tower in order to separate the prills according to their diameter into at least a first fraction and a second fraction, the average diameter of the prills of said first fraction being smaller than the average diameter of the prills of said second fraction; modifying said feeding line to feed said first fraction of prills to the granulator; and installing a line for exporting and storing said second fraction of prills from the solidification section.

7. The method according to claim 2, wherein the prills of said first fraction have an average diameter ranging from 1 mm to 1.7 mm.

Description

(1) The advantages of the invention will emerge even more clearly with reference to FIG. 1, which shows a schematic diagram of the solidification section of a urea plant according to a preferred embodiment of the invention.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

(2) FIG. 1 shows in schematic form a solidification section 1 of a stream 10 of urea melt coming from a synthesis section (not shown) of a urea plant.

(3) Said solidification section 1 essentially comprises a prilling tower 2 which produces prills of varying diameter, a screening device 3 which separates the finer prills, and a granulator 4 wherein the finer prills act as granulation seeds.

(4) Basically, the solidification section 1 operates as follows.

(5) The prilling tower 2 is fed with a first fraction 10a of urea melt and with air 11 in counterflow. Inside said tower 2, proper shower sprinklers (not shown) produce droplets of urea melt which are cooled by the air 11 until complete solidification, producing prills with a non-uniform diameter. An alternative to said shower sprinklers is a rotating drum.

(6) The prilled product 12 leaving the tower 2 is introduced into the screening device 3, which separates the prills into a first fraction 13 and a second fraction 14. The prills of said first fraction 13 have a smaller average diameter than the prills of said second fraction 14.

(7) The prills of the first fraction 13 are conveyed to the granulator 4 where they act as granulation seeds; the prills of the second fraction 14 are instead exported from the solidification section 1 and stored.

(8) The fraction 14 is also referred to as “large” product of the prilling tower 2, while the fraction 13, which is further treated inside the granulator 4, is also referred to as “fine” product of said tower 2.

(9) In some embodiments, the fraction 14 is cooled in a suitable cooler (not shown) prior to storage.

(10) According to the example shown in FIG. 1, the granulator 4 is of the fluid bed type. It is fed with a second fraction 10b of urea melt and with a stream of cooling air 15 which keeps the bed in the fluid state. The urea melt 10b is sprayed onto the prills (seeds) of the first fraction 13, which gradually increase in size, producing the granules 16. The air flow 15 is fed to the granulator 4 via a fan 5.

(11) The granules 16 are sent to a cooling section 6, wherein they solidify to produce the final product 17 ready for storage.

(12) In a variant, the prilling tower 2 and the granulator 4 are fed with streams of urea melt which do not originate from the same stream. Said streams of urea melt may, therefore, have different concentration. For example, the stream feeding the granulator 4 may have a urea concentration smaller than the stream feeding the prilling tower 2.

(13) The contaminated air 18 leaving the granulator 4 contains urea dust and ammonia and is sent to a scrubbing unit 7, where it is generally treated in the presence of water so as to remove the urea dust and the ammonia. In some cases said contaminated air 18 is also treated in the presence of an acid solution, containing for example sulphuric acid, in order to minimize the ammonia losses.

(14) At the output of the scrubbing section 7, a stream 19 of purified air is emitted into the atmosphere and an aqueous solution 20 containing urea is partially recirculated into the scrubbing section 7 as stream 20a via a pump 8. The remaining portion 20b, instead, is exported.

(15) In case the contaminated air 18 is treated in the presence of water and the aforementioned acid solution, the aqueous solution 20 generally also contains salts (for example ammonium sulphate) in addition to urea.

EXAMPLES

(16) Reference is made to a urea plant comprising a prilling tower. Said plant produces 1'000 MTD of urea melt and said urea melt is supplied to the prilling tower, wherein it solidifies into prills. After revamping, a capacity increase of 50% is obtained resulting in a urea production rate of 1'500 MTD. The additional 500 MTD of urea melt obtained in the revamped plant are supplied to a granulator put in series with the prilling tower.

Comparative Example (Prior Art)

(17) Reference is made to the method of EP 2 077 147. The prills obtained in the prilling tower are all fed to the granulator, wherein they act as granulation seeds, producing the final product.

(18) The average diameter of the prills acting as seeds in the granulator is 2 mm. The average diameter of the final product of the granulator is 2.3 mm, according to the following formula:

(19) $D=d.Math.\left(\sqrt[3]{\frac{F}{F_2}}\right)$

(20) wherein:

(21) D=average diameter of the final product of the granulator;

(22) d=average diameter of the prills acting as granulation seeds;

(23) F=total urea melt, namely the urea melt fed to the prilling tower and the granulator;

(24) F.sub.2=urea melt fed to the prilling tower.

(25) Said diameter of 2.3 mm is intermediate between that of the prills and that of conventional granules. Accordingly, the final product has mechanical characteristics superior to prills but inferior to granules.

Example of the Invention

(26) The screening device is set to a dimension threshold of the prills of 2 mm.

(27) 28% of the prills (i.e. 280 MTD of urea) produced in the prilling tower are sent to the granulator wherein they act as feeds, and 72% of the prills (i.e. 720 MTD of urea) are exported and sent to storage. The remaining 780 MTD of the total urea produced in the revamped plant are exported as granules.

(28) The average diameter of the prills acting as seeds in the granulator is 1.7 mm. The average diameter of the final product of the granulator is 3 mm, according to the formula above.

(29) The final product obtained in the granulator with the method of the invention has a higher average diameter than the final product obtained with the method of the prior art. Accordingly, it has mechanical properties which are substantially equivalent to those of a conventional granulated product.