The invention relates to the filtration of soot/ash water slurries. Such slurries are obtained in a number of chemical processes such as chemical gasification processes using heavy hydrocarbon feedstocks. More specifically the invention concerns an improved partial oxidation, gasification process where the soot/ash water slurry emerging after the carbon removal step of such process is filtered off and disposed of directly.

Partial oxidation processes for hydrocarbon feedstocks were developed and commercialized during the 1950 's. The best known processes, such as the Shell gasification process and the Texaco gasification process, have been utilized in a number of commer¬ cial plants.

Such gasification processes utilizing hydrocarbon feedstock normally comprise three principal steps:

Gasification, in which the feedstock is converted into raw synthesis gas in the presence of oxygen and steam.

Waste heat recovery in which high pressure steam is generated from the hot gases leaving the reactor, and

Carbon removal, in which residual carbon contained in the reactor outlet gas is removed in a multistep water wash.

Hereby the unburned carbon from the gasifier will be made into a carbon slurry, an aqueous suspension containing soot and a significant amount of ash, depending on the feedstock, which has to be further processed and recycled.

Thus a serious drawback of such processes is that a certain percentage of the feedstock is not gasified and remains in the form of soot mixed with appreciable amounts of ash from the heavy hydrocarbon feedstock.

Traditionally the soot recovery is handled by two alternative routes:

1. The carbon is recovered by means of pelletising, where a distillate or a residual fuel oil is used to form agglomerates with the carbon particles. The pellets can easily be separated from the water and are recycled to the reactor and/or burned in a carbon oil furnace.

2. Alternatively the carbon slurry is contacted with naphta in an extractor to form naphta soot agglomerates. The agglomerates are subsequently decanted or sieved-off and converted into a pumpable mixture together with the feedstock and recycled to the reactor.

However, as the soot is heavily contaminated with ash the disposal of the soot/ash mixtures has gradually become the most serious problems for such gasification processes.

The possibility to separate the soot/ash mixture by filtration and to dispose of it directly is considered as an attractive solution, but has not been applied on a large scale.

More specifically, filtration has been used to recover soot for special applications, such as adsorbant carbon, conductive carbon and carbon black. However, such applications will not solve the disposal problems in a large gasification plant.

The soot/ash slurry from the carbon separation step will normally contain 0.5-3% unburned carbon and 0.1-2% ash. The ash contains appreciable amounts of Ni, Fe and V. The filtering of such a slurry is extremely difficult. As the water is removed the slurry is gradually turned into a soapy paste which is very difficult to handle by normal filtration means. The final water content of the filtercake will be 85% or higher and the pasty consistency of such a filtercake makes it unsuitable for further handling.

Subsequent combustion will result in excessive caking and the high combustion temperatures needed to burn the soot create severe environment and corrosion problems.

To overcome these handling problems it has been proposed to add other solid matter to the slurry. Thus according to DE-A—4003242 a soot water slurry is mixed with sewage sludge (Klarschlamm) , whereafter the excess water more easily can be removed from such mixture. Thereafter the remaining solid sludge can be deposited, but the heavy metals and other contaminations are not taken care of and the disposal problems are not solved.

The main object of the invention is to provide a method for filtration of a soot/ash water slurry resulting in a filtercake suited for subsequent handling and processing.

Another object of the invention is to carry out filtration to obtain a filtercake with significantly reduced water content forming granules or flakes instead of a soapy paste.

It is another object of the invention to employ the filtration method to provide an improved partial oxidation gasification process in the form of a once through-continuous process to obtain a filtercake suitable for further processing.

Still another object of the invention is to provide a partial oxidation process with no recirculation of ash and unburned carbon to improve the overall efficiency of the gasification process.

These and other objects of the invention are obtained by means of a filtration carried out at low temperatures below 80°C while confining the soot water slurry between movable filter belts exerting a constant line pressure until the filtercake contains less than 80% water, preferably less than 75% water and is no longer soapy or pasty but is tranferred into flakes or agglomer¬ ates which are easily separated and well suited for subsequent transport and handling in a drying and/or combustion process.

To further improve the filtering efficiency the soot slurry is mixed with two different polyelectrolyte flocculation agents; one cationic and the other anionic.

Further essential features of the invention are as defined in the accompanying claims 1-4 and will also appear from the detailed description of the invention below.

Fig. 1 shows a flow sheet of the filtration process.

Fig. 2 is a graph showing the dry matter content of the filtercake at different soot slurry temperatures.

Initial filtering tests in the laboratory revealed that when the dry matter content of the filtercake was increased to 20% or higher, this resulted in the formation of dry flakes or agg- lommerates suitable for further processing. However, choosing carefully the optimal parameters for conventional filtration, using filter aid and optimizing the speed of the filterpress did not give a satisfactory result in realistic plant tests. The water content was still well above 85% and the resulting filtercake not suitable for further processing.

A new test series was then initiated, incorporating a cooling unit in front of the filtration section and using two poly¬ electrolyte flocculation agents, one negatively and one posi¬ tively loaded. The soot slurry was cooled from 95-90°C to 60°C, 50°C etc., and the dry matter content of the filtercake was measured.

The results of this test are given in table 1 below :

TABLE 1

Surprisingly it was found that low temperature increased the efficiency of the filtration as is also illustrated in fig. 2. At slurry temperature > 80°C it is not possible to obtain a filtercake with a satisfactory consistency as the dry matte content then will be below 20%, even if the other filtration parameters are optimized.

Utilizing the results for the initial tests a full scal filtration method has been developed and successfully tested In the flow sheet of fig. 1 is shown a completely integrate gasification process where heavy residue oil is reacted in conventional gasification unit with soot separation.

According to a preferred embodiment of the invention, and a illustrated in fig. 1, the feed 12 is converted in the gasifica tion unit 13 and the gas containing soot/ash is washed in th soot separation step 1. The crude gas 11 is then subjected t purification. The soot/ash water slurry emerging from the soo separation step 1 is initially passed through a cooler 2 to lowe the temperature from approx. 95"C to 20-60°C and fed into a soo slurry holding tank 3. The slurry is then passed through a mixe 4 to administer the flocculation agents from a source 5. Tw flocculants were used, one positively charged polyelectrolyt sold under the trade mark Praestol 611BC (cationic) and on negatively charged polyelectrolyte sold under the trade mar Praestol 2440 (anionic) , both being in the form of a whit polyacrylamide granulate. The flocculants were added to th slurry in a mixer tank 4 as 0.1-0.3% solutions in water. Th total volume of flocculants added was adjusted to between 60-10 ppm and the ratio of cationic : anionic polyelectrolyte wa 1.5:1.

Thereafter the slurry was let into a settling tank 6 where th settled mass was removed at the bottom and excess water remove from the top and returned through pipe 10 to the soot separatio step 1.

An integrated filter unit 7 was installed after the sedimentatio or settling unit 6. However, the sedimentation step is optiona and it is possible to supply the filter unit with slurry from th mixer 4.

The slurry was dewatered while confined on the movable filter 7 consisting of a horizontally movable filterband followed by tw vertically moving filterbands compressed by means of roller pressing the filterbands together to exert a constant pressur until the water content of the filtercake was reduced to < 80% Thereafter the filtercake was released onto a movable conveyo belt, in the form of dry flakes or plates with an averag thickness of approx. 2 mm, and fed to a combustion unit 8. Th product 9 could be handled and further processed without an problems. The filtrate was also directly suited for washing o the filtercake which was carried out continuously and th filtrate could be returned to the soot separation step withou detrimental effects in the filtration process.