[0001] This invention relates to a process for removing silica and/or aluminium bearing
mineral matter and other reactive substances from substances which do not react with
hydrogen fluoride under the same conditions. The reaction with hydrogen fluoride may
be in the gaseous or liquid form.
[0002] It has been known that hydrogen fluoride particularly as a liquid will react with
silica and dissolve same selectively from non-reactive materials such as carbonaceous
matter, for example, coal. However, whilst this reaction has been known it has never
been able to be put into a commercial viable process. The main reasons for this being
that hydrogen fluoride is a particularly dangerous substance and any wastes produced
which include hydrogen fluoride create troublesome disposal problems. Furthermore,
hydrogen fluoride is a very expensive material and the known processes are not economically
viable because they have not shown how the hydrogen fluoride may be recovered and
recycled.
[0003] Many carbonaceous materials, such as coal, oil, tar sands and oil bearing shales
contain a valuable high energy component, i.e., the carbonaceous material, incorporated
with either chemically or physically bound substances which are not desirable because
they are merely ash substances or create pollution problems. Such undesirable substances
are substantially silicon, aluminium and sulphur compounds. These components make
up the major unwanted matter in coal and other carbonaceous fuels.
[0004] Many coals contain ash contents up to 3096 or even in excess of that figure. It is
thus desirable that these coals have their ash contents reduced to amounts which are
more acceptable to the fuel burning consumer. Low ash coals and other fuels, i.e.
with ash contents below 1 %, are very rare and very hard to obtain by conventional
methods. However, these fuels are becoming more in demand due to the need to be able
to burn them directly as a pulverised coal in situations such as diesel engines and
other critical fuel burning apparatus. The conventional methods of cleaning coal such
as washing are generally not satisfactory to reduce the ash content to the low levels
required for the vast majority of coal that is available.
[0005] Elements which are unreactive with HF under certain conditions may be recovered,
using the process of the invention, from reactive associated components such as silicon,
aluminium, sodium or other mineral matters.
[0006] It is thus an object of this invention to ameliorate the abovementioned disadvantages.
[0007] In one broad form the invention provides a process for separating compounds or elements
which do not react with hydrogen fluoride from elements or compounds which do react
with hydrogen fluoride, and recovery for reuse of substantial amounts of the hydrogen
fluoride, said process comprising: (a) reacting feed material with hydrogen fluoride;
(b) separating the resultant product into a gaseous stream and a solids or liquid
stream, characterised in that (c) the gaseous stream is contacted with water at a
temperature and pressure sufficient to reverse the original reaction to regenerate
hydrogen fluoride gas and (d) separating the hydrogen fluoride gas from the solids
and liquid thus formed; and (e) treating the solids-liquid stream from the initial
reaction (a) by dissolving in aqueous hydrogen fluoride solution their compounds and/or
elements that will dissolve in said solution and (f) separating out those that will
not dissolve, (g) washing the undissolved solids to remove hydrogen fluoride solution
and soluble fluorides from said solids and (h) recovering said solution of fluorides
for reuse; (i) treating the liquid stream containing soluble fluorides from step (e)
at a temperature and pressure to drive off the hydrogen fluoride as a gas to be recycled
following condensation.
[0008] In a further broad form the invention provides a process for substantially removing
silica and sulphur from coal comprising the steps of contacting coal with hydrogen
fluoride gas for a time sufficient to convert substantially all of the silica, alumina
and sulphur components to fluoride compounds, at a temperature from 0 to 149°C, separating
the gaseous components from the coal solids, collecting the coal solids; contacting
the separated gaseous component with water at a temperature in the range 104 to 127°C
and a pressure in the range 515 to 791 kPa, to precipitate sulphur and sulphur compounds
from the gas, passing the remaining gas through a heater to raise the temperature
of the gas to a sufficient temperature before contacting the gas for a second time
with water to precipitate silica from the gas and convert the fluorine to gaseous
hydrogen fluoride for recycling.
[0009] The invention will now be described by way of example only with reference to the
accompanying drawing, which is a flow sheet diagram of the process of the invention
with particular reference to coal in accordance with the preferred form of the invention.
[0010] The invention is to be described by its application to fine dried coal, however,
it will be obvious that normal experimental procedure will establish the variables
to be used with regard to feeding other materials to be processed instead of coal.
[0011] Dry fine coal, preferably less than 74 pm and less than 1% moisture, is fed by means
of a vacuum lock 11 feeder into the coal feed bin 10 from where it is metered into
a primary reactor 12. The primary reactor 12 may be a rotary ball mill to further
grind the coal to finer particles whilst the reaction is being carried out. Also introduced
into the primary reactor 12 is gaseous HF 40 which is mixed with the coal at a temperature
range from 0 to 149°C. The reactor 12 and obviously the other components in the system
must be constructed of a material resistant to HF. Very few materials are suitable.
Iron is suitable as long as the HF is concentrated, however it is attacked by dilute
aqueous HF.
[0012] The reaction which takes place in the reactor 12 is allowed to continue for a sufficient
time according to the nature of the feed component before being passed into a separator
13. The separator 13 produces initially two and in a more advanced form, three streams.
The two main streams are a solid stream 42 and a gas stream 74.
[0013] The solid stream comprises coal, any unreacted ash, fluorides of aluminium, copper,
magnesium, manganese, titanium, potassium, sodium and iron. Some low density gases
such as included HF, and water and some of the higher density gases which are produced
by the reaction such as fluorides of silicon and sulphur will obviously also be included
with the solids stream 42, either absorbed onto the surface or in the pores of the
reacted solids.
[0014] The nature of the reaction basically relies on the known reaction of HF with various
reactive solids to produce the fluorides thereof. The gaseous stream from the separator
13 is preferably passed through a filter to remove entrained solids and is divided
into two streams 41 and 74, one of lighter gases 41 and one of the heavier gases 74.
The reaction in the reactor 12 produces gaseous fluorides at a temperature, from 0
to 149°C.
[0015] With coal the main fluorides formed in the gaseous state are silicon fluorides and
sulphur fluorides. Some gaseous arsenic fluorides may also be formed.
[0016] It is preferable to form silicon tetrafluoride and sulphur tetrafluoride in the gaseous
form. The gaseous stream from the reactor 13 as mentioned above is divided into a
light stream 41 and a heavy stream 74, the light stream comprising substantially hydrogen
fluoride gas which is the excess gas from the reaction and any water vapour in the
gaseous form. The gaseous stream 74 of heavier gases i.e. the silicon and sulphur
fluoride gases leaving the separator 13 is heated and compressed in a compressor 14
to a temperature of from 104°C to 127°C at a pressure from 515 to 791 kPa and is then
contacted following this compression with liquid water (15A) at similar temperature
and pressure in a contacting vessel 15.
[0017] In the water-contacting vessel 15 the fluorides of sulphur react to form non-gaseous
sulphur crystals or sulphur compounds. The reduction of the sulphur from its fluoride
form forms hydrogen fluoride gas which is basically the reverse of the reaction from
the formation of the sulphur fluorides back in the reactor 12. Thus, a certain amount
of the HF gas has been regenerated at this point. At this temperature and pressure
the hydrogen fluoride solubility in water is low.
[0018] The liquor from the contacting vessel 15 is withdrawn from the bottom thereof and
treated to remove 63 the sulphur-bearing compounds by way of say filtration 16 and
the spent liquor is recycled 62 back to the vessel 15. The sulphur compounds are thus
removed 63 from the system. The gaseous stream then leaves the vessel 15 containing
substantially silicon tetrafluoride, water and hydrogen fluoride gas, the water being
in the gaseous form. Partial separation of these components is achieved in a density
separator 17 with HF
(g
) and H
20
(g
) being extracted 58. The remaining gaseous stream from separator 17 containing silicon
fluorides and gaseous water is heated to a temperature from 427 to 482°C at a pressure
from 515 to 791 kPa in a vessel 18. Furthermore, in vessel 19 the gas is contacted
with liquid water (19A) at a temperature from 104°C to 127°C and 515 to 791 kPa in
vessel 19. The silicon tetrafluoride is reduced in this vessel 19 to silicone dioxide
(silica) and the HF gas is thus regenerated and removed 59 for recycle. The liquor
from contacting vessel 19 is withdrawn from the vessel, filtered 20 or passed through
any other liquid separation means and the silica crystals and other solids are removed
60. The spent liquor 61 from the solid liquid separator 20 is returned to the vessel
19.
[0019] As the process proceeds the aqueous liquor which passes through vessels 15 and 19
become saturated with trace compounds which are being carried over in the gas stream
from the separator 13. These trace compounds are removed from the process by bleeding
liquor (not shown) from the two loops. The solids stream 42 from the separator 13
is countercurrently purged 44-4.3 with gaseous HF in vessel 21. This prevents the
carrying over of any other gases in the stream as it passes for further processing
of the solids material. The solids from vessel 21 are fed into a secondary reactor
22. In the secondary reactor 22 the solids are mixed with aqueous HF solution 46 which
is preferably maintained at around 20 to 30 mass percent HF concentration. In the
reactor 22 the solid fluorides of aluminium are dissolved and any unreacted alumina
from the primary reactor 12 is also dissolved. Virtually all other coal ash derived
solids from the primary reactor 12 are also dissolved, the coal remains undissolved
and untouched by the HF. The mixed liquid-solid stream from the secondary reactor
22 is thus drawn off and fed to a solid-liquids separator 23 such as a settling tank.
In the separator 23 the solids are removed from the liquor. The liquor from the separator
23 is then passed through a heater 24 which raises a stream temperature and pressure
to from 104°C to 127°C and from 515 to 791 kPa, thereby reducing the solubility of
the HF gas and hence the solubility of fluorides of aluminium causing them to crystallise.
The remaining stream is then fed to a solids-liquid separator 25 where the solids
are separated from the liquid-gas stream. The solid stream from the settler 25 is
washed with water 80 in washer 26 to remove, in stream 70, traces of HF and water
soluble fluorides. The solids are then heated in heater 27 to a temperature from 1204°C
to 1316°C at which temperature the fluorides of aluminium vaporise. These vapours
are drawn off 72 from the heater 27 and condensed to form solid aluminium fluoride
69 in condenser 28. Residual excess gas is removed through line 68. The residue in
heater 27 is cooled to solids 71 which are predominantly oxides and/or fluorides of
magnesium, manganese, calcium and aluminium. The liquor-gas stream from settler 25
contains dissolved fluorides of titanium, potassium and sodium. This stream is split
in gas-liquid separator 29 with the bled liquid stream fed to evaporator 30, in which
the dissolved solids are concentrated and then fed to heater 31 at 260 to 371 °C.
Steam generated in the evaporator 30 is passed to the atmosphere through line 64.
[0020] In heater 31 the fluorides of titanium vaporise. These vapours are drawn off from
the heater 31 and condensed to solid titanium fluoride 67 in condenser 32. Residual
excess is removed through line 65.
[0021] The residue in heater 31 is removed 66 and cooled to solids, predominantly fluorides
of potassium and sodium.
[0022] Solids from settler 23 are predominantly coal with traces of iron which are wet with
aqueous HF solution. The total non-gaseous stream from settler 23 is washed in water
47 in washer 33 followed by washing with diluted ammonia solution 48 in washer 34.
The solids are separated from the bulk of the liquors which is removed through line
51. Similarly, excess liquor is removed from the solids in washer 33 via line 50.
The stream is then passed to vessel 35 where it is again washed in water 49. The ammonia
wash 34 dissolves residual hydrogen fluoride and fluorides from the coal. The wash
water liquor is preferably conducted in a countercurrent manner with regard to vessels
33 and 35 thus it is recycled 47 from vessel 35 to vessel 33.
[0023] The washed coal is then dried by hot air 52 in dryer 36 and fed to separator 37 for
removal of iron 56 by density separation. Coal in its clean state is then removed
via line 57.
[0024] The main stream 73 from the splitter 29 is cooled in heat exchanger 38 to redissolve
the hydrogen fluoride vapours in water. This regenerates aqueous HF solution for recycle
45 back in the secondary reactor 22.
[0025] Hydrogen fluoride and water gas mixtures from stages 13, 17, 19, 28 and 32 are thus
recycled as feed to stages 12 and 21. Dilute hydrogen fluoride from stages 26 and
33 is concentrated by distillation for reuse in stage 22. Hydrogen fluoride vapour
in the air stream from dryer 36 is removed by scrubbing with aqueous lime in tower
39. The aqueous line is fed to tower 39 via line 54 and the resultant solution is
removed via line 55. Residual excess gas is removed via line 53.
[0026] The above preferred embodiment has described the process for utilising hydrogen fluoride
for the extraction of coal from its unwanted ash and other pollutant-type materials.
Using the above method it is possible to obtain ash contents of less 0.1%. Of course
the degree of ash remaining is determined on a number of factors, the main ones of
which are the degree of reaction of the initial reactor and the efficiency of the
separation stages and the second reaction stage. Whilst it is preferred to use fine
powdered coal, experiments conducted using lump coal material of the fine powdered
coal have proven to be about equally as effective. The hydrogen fluoride effectively
reacts with the included ash in the coal to leave a honey-combed clean cool structure.
[0027] The above process can also be used to recover oil from tar sands and shale oil deposits.
By feeding tar sands or ground shale containing shale oil into the primary reactor
12 basically the same reactions occur as with coal. The "oil" may thus be extracted
along the path of the coal solids with minor variations to the detailed parts of the
process in an oil form. In all of the above processes the amount of HF which is required
of fresh make up to the system after allowing for recycle, will also depend upon how
the various fractions of the by-products are removed from the process for example
it may be very desirable to remove magnesium and aluminium in a fluoride form. Particularly,
aluminium fluoride which is a valuable by-product as it is an intermediate material
in the alumina process, thus, its value in the aluminium fluoride form may well exceed
its value in returning to an alumina form and recovering the fluorine for reconstitution
to HF.
[0028] The process may furthermore be used for the extraction of metal values from ore deposits
which comprise substantial amounts of silica and/or iron oxide and/or magnesium oxides.
As there are many low grade mineral deposits which contain large amounts of valuable
metals in low concentrations suitable economic recovery methods at present are not
available.
[0029] The majority of mineral processing methods require the use of large quantities of
water for treating the minerals. This obviously is a problem in dry areas of the world
where water is in very short supply, thus low grade ores as they are too expensive
to transport in their unconcentrated state cannot be processed at the mine site and
are thus not presently of any real value. Furthermore, large water use requires large
energy use which further reduces the viability of any recovery metals from low grade
deposits.
[0030] Mined ore usually contains as major constituent silica which may in its various forms
make up to 90% or more of the ore. If silica is not the major component then iron
oxide is often a major component. Iron oxide is usually present with silica in most
deposits. Therefore, to concentrate the valuable minerals contained in up to 10% of
the ore it is essential to separate these minerals from silica and iron oxide.
[0031] The above prescribed process for treatment of coal is thus applicable to silica,
magnesium, iron-type ores. The ore which has been mined aground to an acceptable size
is fed into the process in the same manner as is the coal. The hydrogen fluoride in
the reactor 12 converts silica, sulphur and arsenic compounds to gaseous fluoride
compounds. These gases are removed from the reactor after passing through separator
13. The gases may be treated in identical manner to the treatment of gases in the
above described process for coal. The solid products from the separator 13 are removed
and passed to a solids separation device 22 which may separate the solids of a specific
gravity basis. Most of these solids are metal fluorides and include those metals which
comprise nearly all of the valuable metals likely to be included in the ore, such
as chromium, titanium, cobalt, silver, nickel, tin, lead, copper, gold and other rare
metals. Some metals may require catalytic or temperature variations in the reactor
to cause conversion to fluoride form. These variables are obviously a. matter particular
to the type of metal which is to be extracted or converted to fluoride. It is possible
to selectively reclaim metal fluorides formed because they nearly all have significantly
different solubilities. Thus separation by contact with water in some cases temperature
and pressure variations will cause precipitation of certain metal fluorides and thus
recovery of same following concentration by carrying out the reverse step of the reaction
which formed the metal fluoride, the metals can be reclaimed in their concentrated
form.
[0032] It is to be noted that iron oxides do not react with concentrated hydrogen fluoride
in the acid form or gaseous form, however, they do react with dilute hydrogen fluoride
in liquid form, therefore if contact of the iron oxides is only with the gaseous hydrogen
fluoride then no reaction takes place with the iron and these iron oxides may be cleaned
free of all other elements that have reacted with the HF gas, which means that they
can then be passed for use as a raw material for steel production or just simply removed
from the valuable metal.
[0033] It is to be noted that in the above process there is substantial recycle of HF and
valuable by-products are also produced, thus allowing the viability of the process
to be proven.
1. A process for separating compounds or elements which do not react with hydrogen
fluoride from elements or compounds which do react with hydrogen fluoride, and recovery
for reuse of substantial amounts of the hydrogen fluoride, said process comprising:
(a) reacting feed material with hydrogen fluoride; (b) separating the resultant product
into a gaseous stream and a solids or liquid stream, characterized in that (c) the
gaseous stream is contacted with water at a temperature and pressure sufficient to
reverse the original reaction to regenerate hydrogen fluoride gas and (d) separating
the hydrogen fluoride gas from the solids and liquid thus formed; and (e) treating
the solids-liquid stream from the initial reaction (a) by dissolving in aqueous hydrogen
fluoride solution their compounds and/or elements that will dissolve in said solution
and (f) separating out those that will not dissolve, (g) washing the undissolved solids
to remove hydrogen fluoride solution and soluble fluorides from said solids and (h)
recovering said solution of fluorides for reuse; (i) treating the liquid stream containing
soluble fluorides from step (e) at a temperature and pressure to drive off the hydrogen
fluorides as a gas to be recycled following condensation.
2. The process of claim 1 characterized in that the gaseous stream prior to being
fed to step (c) is separated to remove hydrogen fluoride gas for recycling.
3. A process for substantially removing silica and sulphur from coal comprising the
steps of contacting coal with hydrogen fluoride gas for a time sufficient to convert
substantially all of the silica, alumina and sulphur components to fluoride compounds,
at a temperature from 0 to 149°C, separating the gaseous components from the coal
solids, collecting the coal solids; contacting the separated gaseous component with
water at a temperature in the range 104 to 127°C and a pressure in the range 515 to
791 kPa (60 to 100 psig) to precipitate sulphur and sulphur compounds from the gas,
passing the remaining gas through a heater to raise the temperature of the gas to
a sufficient temperature before contacting the gas for a second time with water to
precipitate silica from the gas and convert the fluorine to gaseous hydrogen fluoride
for recycling.
4. The process of claim 3 characterized in that the step of contacting the gaseous
stream with water to precipitate out sulphur and its compounds is carried out at about
115°C (240°F) and about 650 kPa (80 psig).
5. The process of claim 3, characterized in that the solids stream from said solids-gas
separation step is washed in aqueous HF solution, to dissolve substances soluble in
aqueous HF, passed through a solids-liquid separator, recovering the solids, washing
the solids to remove soluble fluorides including hydrogen fluoride; recovering the
coal solids; treating the liquid stream from the solids-liquid separator by-
(i) heating the stream to about 105°C to 125°C (220 to 260°F) at a pressure from 515
to 791 kPa (60 to 100 psig) to induce crystallization of fluorides of aluminium;
(ii) separating the crystallized solids from the liquid-gas stream;
(iii) separating the gas phase from the liquid phase, said gas phase being condensed
and recycled to the aqueous HF solution supply; and
the liquid phase being removed.
1. Verfahren zum Abtrennen von nicht mit Fluorwasserstoff umsetzbaren Verbindungen
oder Elementen von mit Fluorwasserstoff umsetzbaren Elementen oder Verbindungen und
zum Rückgewinnen beträchtlicher Mengen des Fluorwasserstoffs zur Wiederverwendung,
wobei (a) ein Ausgangsgut mit Fluorwasserstoff umgesetzt und (b) das dabei erhaltene
Produkt in einen Gasstrom und einen Feststoff-oder Flüssigkeitsstrom getrennt wird,
dadurch gekennzeichnet, daß (c) der Gasstrom mit Wasser bei einer Temperatur und einem
Druck in Berührung gebracht wird, die genügen, um durch eine Umkehr der ursprünglichen
Reaktion Fluorwasserstoff durch Regenerierung zurückzugewinnen, (d) das Fluorwasserstoffgas
von dem auf diese Weise gebildeten Feststoff und der auf diese Weise gebildeten Flüssigkeit
abgetrennt wird, (e) der bei der ersten Reaktion (a) erhaltene Feststoff- Flüssigkeitsstrom
derart behandelt wird, daß in einer wäßrigen Fluorwasserstofflösung die in dieser
löslichen Verbindungen und/oder Elemente des Feststoff-Flüssigkeitsstroms aufgelöst
werden, (f) die nicht löslichen Verbindungen und/oder Elemente abgetrennt werden (g)
die nicht gelösten Feststoffe gewaschen werden, um Fluorwasserstofflösung und lösliche
Fluoride von dem Feststoff zu entfernen, und (h) die genannte Lösung von Fluoriden
zurückgewonnen wird, (i) der im Schritt (e) erhaltene, lösliche Fluoride enthaltende
Flüssigkeitsstrom bei einer solchen Temperatur und einem solchen Druck behandelt wird,
daß der Fluorwasserstoff als ein Gas abgetrieben wird, das nach seiner Kondensation
zurückgeführt wird.
2. Verfahren nach Anspruch 1, dadurch gekennzeichnet, daß der Fluorwasserstoff aus
dem Gasstrom vor dessen Zuführung zum Schritt (c) abgetrennt und zurückgeführt wird.
3. Verfahren zum im wesentlichen vollständigen Entfernen von Siliciumdioxid und Schwefel
aus Kohle, dadurch gekennzeichnet, daß Kohle bei einer Temperatur von 0 bis 149°C
so lange mit Fluorwasserstoffgas in Berührung gebracht wird, daß der Gehalt an Siliciumdioxid,
Aluminiumoxid und Schwefel im wesentlichen vollständig in Fluoride umgewandelt wird,
daß die gasförmigen Bestandteile von den Kohlefeststoffen abgetrennt werden, daß die
Kohlefeststoffe gesammelt werden, daß die abgetrennten gasförmigen Bestandteile bei
einer Temperatur im Bereich von 104 bis 127°C und einem Druck im Bereich von 515 bis
791 kPa mit Wasser behandelt werden, um Schwefel und Schwefelverbindungen von dem
Gas zu entfernen, daß das verbleibende Gas durch eine Heizeinrichtung geführt wird,
um das Gas auf eine genügend hohe Temperatur zu erhitzen, bevor es zum zweiten Mal
mit Wasser in Berührung gebracht wird, um Siliciumdioxid aus dem Gas auszufällen und
das Fluor in gasförmigen Fluorwasserstoff zu verwandeln, der zurückgeführt wird.
4. Verfahren nach Anspruch 3, dadurch gekennzeichnet, daß zum Ausfällen von Schwefel
und seinen Verbindungen der Gas- strom bei etwa 115°C und 650 kPa mit Wasser in Berührung
gebracht wird.
5. Verfahren nach Anspruch 3, dadurch gekennzeichnet, daß der bei der Feststoff-GasTrennung
anfallende Feststoffstrom in einer wäßrigen HF-Lösung gewaschen wird, um in wäßrigem
HF lösliche Substanzen herauszulösen, und dann durch einen Fest-Flüssig-Scheider geführt
wird, worauf die Feststoffe gewonnen und dann gewaschen werden, um lösliche Fluoride,
einschließlich von Fluorwasserstoff, zu entfernen, worauf die Kohlefeststoffe zurückgewonnen
und der in dem Fest-Flüssig-Scheider anfallende Flüssigkeitsstrom folgenden Behandlungen
unterworfen wird:
(i) Zum Kristallisieren von Aluminiumfluorid wird der Strom unter einem Druck von
515 bis 791 kPa auf etwa 105 bis 125°C erhitzt;
(ii) der kristalline Feststoff wird von dem Flüssigkeits-Gas-Strom entfernt;
(iii) die Gasphase wird von der flüssigen Phase getrennt und nach ihrer Kondensation
zu dem Vorrat an wäßriger HF-Lösung zurückgeführt, und die flüssige Phase wird beseitigt.
1. Procédé de séparation de composés ou éléments ne réagissant pas avec l'acide fluorhydrique
à partir de composés ou éléments qui réagissent avec l'acide fluorhydrique et de récupération
afin de réutiliser des quantités importantes d'acide fluorhydrique, ledit procédé
comprenant les étapes suivantes:
a) on fait réagir le matériau de départ avec l'acide fluorhydrique;
b) on sépare le produit résultant dans un flux gazeux, un courant de solids ou flux
liquide, caractérisé par le fait que
c) on met en contact le flux gazeux avec de l'eau, à une température et une pression
suffisantes pour inverser la réaction initiale afin de régénérer l'acide fluorhydrique
gazeux et
d) on sépare l'acide fluorhydrique gazeux des solides et du liquide ainsi formés et
e) on traite le courant liquide-solids provenant de la réaction initiale (A) en faisant
dissoudre dans une solution aqueuse d'acide fluorhydrique, leurs constituants et/ou
les éléments qui se dissolvent dans ladite solution et
f) on sépare ceux qui ne se dissolvent pas,
g) on lave les solides non dissous pour enlever la solution d'acide fluorhydrique
et les fluorures solubles desdits solides, et
h) on récupère ladite solution de fluorures pour les réutiliser,
i) on traite le flux liquid contenant les fluorures solubles, provenant de l'étape
(E) à une température et une pression permettant d'enlever l'acide fluorhydrique sous
forme gazeuse pour le recycler après condensation.
2. Procédé selon la revendication 1, caractérisé par le fait que l'on sépare le flux
gazeux avant de lui faire subir l'étape C, afin de séparer l'acide fluorhydrique et
le recycler.
3. Procédé pour séparer notamment la silice et les sulfures, du charbon comprenant
les étapes suivantes:
on met en contact le charbon avec de l'acide fluorhydrique gazeux pendant un temps
suffisant pour convertir sensiblement toute la silice, l'alumine et les composés sulfurés
en composés fluorures, à une température de 0 à 149 degrés C,
- on sépare les composés gazeux des parties solides de charbon,
- on recueille les parties solides de charbon,
-on met en contact le constituant gazeux séparé avec de l'eau à une température comprise
dans l'intervalle de 104 à 127 degrés C et à une pression comprise dans l'intervalle
de 515 à 791 kPa (60 à 100 PsiG) pour précipiter le soufre et les composés sulfurés
des gaz,
- on fait passer le gaz restant dans un dispositif de chauffage pour élever la température
du gaz à une température suffisante avant de mettre en contact le gaz pour une seconde
période, avec de l'eau, afin de précipiter la silice à partir du gaz et convertir
le fluor en acide fluorhydrique gazeux pour être recyclé.
4. Procédé selon la revendication 3, caractérisé par le fait qu l'étape de mise en
contact du flux gazeux avec l'eau afin de précipiter le soufre et ses composés, est
effectuée à environ 115 degrés C. (240 degrés F) et à environ 650 kPa (80 Psig).
5. Procédé selon la revendication 3, caractérisé par le fait qu'on lave le courant
de solids provenant de l'étape de séparation desdits solides et des gaz, dans une
solution aqueuse de HF afin de dissoudre les substances solubles dans le HF aqueux,
on le fait traverser un séparateur solides-liquide, on récupère les solides, on lave
les solides pour enlever les fluorures solubles, y compris l'acide fluorhydrique,
on récupère les parties solides de charbon, on traite le flux liquide provenant du
séparateur solides-liquide en effectuant
I) le chauffage du flux à environ 105 degrés C à 125 degrés C (220 degrés F à 260
degrés F), à une pression de 515 à 791 kPa (60 à 100 Psig) pour induire la cristallisation
des fluorures d'aluminium
II) la séparation des solides cristallisés du flux liquide-gaz
III) la séparation de la phase gazeuse de la phase liquide, ladite phase gazeuse étant
condensée et recyclée à l'amenée de la solution aqueuse de HF et la phase liquide
étant enlevée.