FR2666098A1 - Plant for recovering raw materials from special steel slags - Google Patents

Abstract

Plant for recovery of raw materials and of usable residues from special steel slags, which is used to produce slag that can be employed as a fertilizer for agriculture, with a particle of 0 to 4 mm, slag with a particle larger than 4 mm and metallic particles that can be employed as raw material. The plant performs a density separation of the initial slag, based on a selective classification of this slag by means of screens (4, 21, 23), mills (19, 27) and pneumatic tables (14, 31, 30) which are suitably arranged.

Description

 The invention relates to a method for recovering and saving the raw materials contained in the slag produced in the production of steels, for example special steels.

 Until now, various methods of recovering non-ferrous metals such as aluminum, copper, stainless steel, etc. have been known from scrap. Some of these methods adopt flotation devices that use water and which take advantage of the density differences between the elements as separation means.

 This process is not directly related to the object of the present invention, and it is very expensive because it requires a preparation of water which consists in supplying it with different substances. In addition, it requires proper decanting of the sludge and its installation requires a lot of space, occupying a large area on the ground.

 Another known method for the exploitation of this waste consists in placing the scrap in screens which separate the sterile material and deposit it on conveyor belts. On both sides of the belt are located non-ferrous material detectors which activate separators, which divert the non-ferrous material to mouths which transmit it to other evacuation belts.

 This method has the disadvantage of removing sterile materials without taking any advantage of them, so that, because of their own characteristics, these materials cannot be usefully used.

 The Applicant does not know of any specific process adopted for slag from the manufacture of stainless steels which makes it possible to take advantage of the slag which accompanies the metallic material and to recover as raw material of first quality, 100% of the metallic fraction, which constitutes the concrete objects of the present invention.

The steels to which the process according to the invention applies are those classified in the F300 series,
F320, which, as we know, have the property of being non-magnetic. The particularity of the present process resides in the fact of avoiding this drawback by adopting the densimetric separation of its components, and making it possible to obtain slag of perfect purity.

With the method according to the invention, it is possible to separate slag which will be designated by type A, which have a particle size between 0 and 4 mm, and which, with the incorporation of phosphate, are perfectly usable as fertilizer for Agriculture. The chemical composition of these type A slag is as follows% SiO2 34,% P205 <0.001% Cr203 4.5% Fe203 2.4% Mn 2.8% MgO 6.8% Oca 42.4% Cu <0.005% Mo 0.02% S 0.16% Zn 0.01
The slag which will be designated by type B, has a particle size greater than 4 mm, which perfectly meets the technical specifications in force for use as a flexible underbody in roads. These slag can also be marketed as components for the glass industry.

Finally, the metallic material, which, as has been pointed out, is a first quality raw material, returns directly to the steelworks with the following effects
the process according to the invention begins with the pouring of the slag material from the steelworks into a receiving hopper. This slag generally has a particle size which varies between 0 and 300 mm.

The hopper sends the material to a conveyor belt in the head of which is an electromagnetic separating drum which ensures the elimination of any ferruginous materials that the whole of the treated scorle could possibly contain, this in order to guarantee the final purity of the steel recovered. At the end of this purification, the remaining material is deposited in a chute of adequate capacity, for example, of 70 tonnes / hour, with the aim of uniformly regulating the flow of material sent to the installation.

 It is from this stage that the process which characterizes the invention really begins.

 From the aforementioned chute, the material is sent to a vibrating pre-screen feeder which performs a first classification between 0 and 70 mm with a production of 60 to 70 tonnes / hour, this material being sent to a screen which performs a second classification between the fraction from 0 to 10 mm and the fraction from 10 to 70 mm. The rest of the material has a particle size between 70 and 300 mm.

 The material of the fraction between 0 and 10 mm is sent to a rotary dryer of 1 meter by 6 meters and having a production capacity of 15 tonnes / hour.

More specifically, the purpose of this classification is that the material with high hygroscopic power is sent to said dryer to bring it to a maximum humidity of 2%, which is the humidity recommended for the proper functioning of the screens placed in the downstream process.

 Under these conditions, this already dry material is poured into a silo and, at the right time, the material of the grain size class from 0 to 70 mm is also deposited in the same silo.

 In this first part of the process, the remaining material, with a particle size of between 70 and 300 mm, is sent to a primary jaw crusher which crushes it to a thickness of between 10 and 70 mm, with a production of 40 tonnes / hour and this material is in turn poured into the silo by means of a tortuous trans belt.

In this way, inside the silo, there are particles with a particle size between 0 and 10 mm and between 10 and 70 mm, which is entirely poured out by a feeder into a vibrating screen with three widths of openings, 1, 4 and 10 mm respectively, with the aim of dividing the material according to the following particle size
-0 to 1 mm
- i to 4 mm
- 4 to 70 mm
The material from 0 to 1 mm consists of slag and oxides, without any metallic component, and it is discharged by means of a belt into a storage area, thus constituting the type A slag mentioned at the beginning, which is perfectly usable for agriculture.

 The material from 1 to 4 mm is in turn transferred to a pneumatic table which performs a densimetric separation of the slag, which floats on a bed of compressed air passing through an inclined metal fabric which is rotated and va back and forth, so that the slag is expelled at the bottom and the metal parts at the top.

 This operation produces slag between 1 and 4 mm in size, which is on the belt which transfers the slag from 0 to 1 mm in the storage area.

 The metallic constituents of 1 to 4 mm, in fact pure, are sent to a product storage hopper.

 The material from 4 to 70 mm, which leaves the first aforementioned silo, is sent to primary crushers, of the rotary gravimetric type, installed in bypass, which grind the material to a grain size of 0 to 30 mm and then send it to a vibrating screen which ensures a classification of the material.

In this screen, a classification of the material is carried out which gives two particle size classes:
- 0 to 4 mm
- 4 to 30 mm
The material of the particle size class from 0 to 4 mm is sent to a Mohansen type screen.

The material from 4 to 30 mm is sent to a second silo and, from there, to secondary crushers of the impact type arranged in diversion, which carry out the following grinding - 5 * of material from 10 to 30 mm - 10% "" 5 to 10 n 5 50% "" 2 2.5 to 5 n - 35% n T 'r' O to 2.5 n
All this material is entirely sent in turn to the aforementioned Mohansen screen, in which the material of the particle size class from 0 to 4 min was already located and, in this screen, the material is classified as follows
- grain from 0 to 1 mm, transferred by a conveyor belt to the storage area.

 - grain from 1 to 4 mm, sent to the pneumatic table in which it is treated jointly with that which arrives from the first screen mentioned above.

 - grain from 4 to 15 mm, which is sent to a second pneumatic table. Here, we separate the slag from 4 to 15 mm which is sent to the second silo and the resulting metal, which is perfectly purified and transferred to the product storage hoppers.

 - grain of 15 to 30 mm, also sent to the second pneumatic table which separates the slag from 15 to 30 mm from the metal. The slag is returned to the second silo and the metal is sent to the product storage hoppers.

 The slag returned to the second silo can be reprocessed when necessary, or else it can be extracted from the silo, to constitute the type B slag to which reference was made at the beginning of this memo.

Other characteristics and advantages of the invention will be better understood on reading the detailed description which follows, with reference to the attached drawing in which the installation according to the invention has been represented and the following has been represented as follows
The slag material from E the steelworks is routed to inlet 1 of the installation, passing beforehand over the magnetic head which is responsible for separating from the slag any ferruginous materials. This material is then transferred to the chute 3 with a capacity of 70 tonnes / hour, the function of which is to uniformly regulate the flow of the material arriving at the installation.

 The chute transmits said material to the assembly 4 which is a vibrating pre-screen feeder assembly in which the separation of the particles from 0 to 10 mm, which pass through the line 8 and from 10 to 70 mm, which pass through the line 7.

 This vibrating pre-screening feeder 4 also provides a material of a particle size class of 70 to 300 mm, which is sent to the jaw crusher 5, which breaks it up into a particle size class of 10 to 70 mm, with a throughput of some 40 tonnes / hour. This material is then sent to line 6.

 The particles of the belt or line 8 pass through the rotary dryer 9 which imparts to them the appropriate degree of humidity, as indicated above.

 The three belts 6, 7 and 8 meet at silo 10 for further processing of the material.

 This silo 10 is equipped with a feeder delivering on a vibrating screen with three openings, from where leaves, by line 11, a material which is constituted by particles of 0 to 1 mm, another material leaving by line 13 , composed of particles from 1 to 4 mm, and a third material composed of particles from 4 to 70 mm leaving via line 18.

 The particles from 0 to 1 mm which circulate on the belt 11 are transferred to the storage zone 12, since they are only axial slag without metallic component. This belt has a flow capacity of approximately 10 tonnes / hour.

 The particles of 1 to 4 mm which are transported by the belt 13 arrive at the pneumatic table 14 equipped with the cyclone 15 at a flow rate of approximately 20 tonnes / hour. This assembly separates the slag which is transferred by the belt 16 to the storage area 12. The metallic particles produced are sent by the belt 17 to a scale 36 and from there to the storage hoppers 34 and 35.

 From the silo 10 and the corresponding screen, outwards, as indicated above, particles of a particle size class from 4 to 70 mm which are conveyed by the belt 18 to the shredders 19 installed in bypass . These mills are of the rotary-gravimetric type and grind the material received with a production rate of 30 to 40 tonnes / hour, reducing it to an average particle size of 0 to 30 mm, which are deposited on the belt 20.

 The belt 20 reaches the screen 21 in the first place. This screen is vibrating and is equipped with means for classifying the material, to supply material from 0 to 4 mm and from 4 to 30 mm.

 Material from 0 to 4 mm is deposited on the belt 22 to reach the screen 20 and that from 4 to 30 mm is stored in the silo 26, to be sent to the belt 22a in the direction of the secondary crushers 27, of the impact type. , which are arranged in bypass as indicated.

The grinders 27 in question carry out a grinding which gives a particle size of 0 to 30 mm and with the following approximate classification - 5% from 10 to 30 mm - 10% from 5 to 10 mm - 50% from 2.5 to 5 mm - 35% from 0 to 25 mm
All of this material as well as that of the particle size class from 0 to 40 mm, carried by the belt 22, reaches the screen 23, of the Mohansen type, which performs the following distribution.
- Slag from 0 to 1 mm, which is sent by the belt 25 to the belt 11 to be sent to the storage area 12.

 - Material from 1 to 4 mm, transmitted by the belt 24 to the pneumatic table 14 in which it is treated in the same way as that which arrived at this table by the belt 13 coming from the silo and screen 10.

 - Material from 4 to 15 mm, which is deposited on the belt 29 leading to the pneumatic table 31. This table performs the separation of the metal, which is sent to the scale 36 and the hoppers 34-35, and the slag, which is transported by the belt 32 to the silo 26.

 - Material from 15 to 30 mm, which is transported by the belt 28 to the pneumatic table 30, which sends the metal to the scale 36 and to the hoppers 35-34 and the slag to the silo 26, by the belt 32.

Claims (1)

 1. Process for recovering raw materials from special steel slag, in particular, stainless steel slag which contains nodules with a particle size of 0 to 300 mm, which are transported on a conveyor belt end of which is disposed a magnetic drum separator intended to collect the possible ferruginous materials, characterized by the following stages  A. a first classification of the slag, carried out in a vibrating pre-screen feeder (4) and used to produce particles from 0 to 70 mm and from 70 to 300 mm, the particles from 0 to 70 mm being sent to a screen to undergo a second classification which provides particles from 0 to 10 mm and from 10 to 70 mm, the particles from 70 to 300 mm being sent by a slide to a jaw crusher (5) and are reduced to the class from 10 to 70 mm , the whole being sent to a silo (10) after prior introduction of the material from 0 to 10 mm in a rotary dryer (9).  B. the material of the silo (10) is poured into a screen with three openings, of 1, 4 and 10 mm passage, in order to provide particles of 0 to 1 mm, from 1 to 4 mm and from 4 to 70 mm , the material from 0 to 1 mm, which is composed of slag and oxides devoid of metalic components, being sent to a conveyor belt (11) and reaching the storage zone (12), and the material from 1 to 4 mm, being sent by another belt (13) to a pneumatic table (14) which performs the densimetric separation between the less dense slag and the metal part, this slag of 1 to 4 mm being transferred to the storage area and the metal part from 1 to 4 mm to hoppers (34, 35) for storing the product. Mohansen (23).  C. the material from 4 to 70 mm from the silo is transferred to two primary crushers (19) of the rotary gravimetric type, arranged in bypass, which are responsible for grinding the material into particles of 0 to 30 mm, which are deposited on a conveyor belt (20) sending them to a vibrating screen (21) which gives a classification of the material in classes from 0 to 4 mm and from 4 to 30 mm, the material from 0 to 4 mm being sent to a screen ( 23) of the Mohansen type while the 4 to 30 mm material is sent to a second silo (26) and, from there, to secondary crushers (27) of the impact type arranged in bypass, which grind it according to the following distribution 5% from 10 to 30 mm, 10% from 5 to 10 mm, 50% from 2.5 to 5 mm and 35% from 0 to 2.5 mm, and is also screened  D. of the Mohansen screen (23), the material is divided into particles of 0 to 1 mm, which are sent to the storage area (12) by belts (25, 11), in particles of 1 to 4 mm, which are transferred to the first pneumatic table (14) where they are also treated, in particles of 4 to 15 mm, sent 9 a second pneumatic table (31) which separates the slag from 4 to 15 mm, which is sent to the second silo (26) by a belt (32), of a metal part of 4 to 15 mm, which is sent to storage hoppers (34, 35), and in particles of 15 to 30 mm which are sent to a three me pneumatic table (30) which separates the slag from 15 to 30 mm, which is returned to the second silo (26), from the metal from 15 to 30 mm, which is poured into the storage hoppers (34, 35).  E. slag from 4 to 15 mm and from 15 to 30 mm are reprocessed.