GB2134920A - Upgrading heavy hydrocarbons employing a diluant - Google Patents

Abstract

Heavy crude oil 12 is mixed with a diluent 18 prior to distillation to produce gaseous hydrocarbon products, overhead liquid hydrocarbons (from which recycle diluent 16, suitably boiling in the range 150-800 DEG F, is recovered) and residuum 60, suitable for delayed coking at 66 and 68 to produce metallurgical coke. The mixture of crude oil and diluent can be subjected to dehydration at 22 and desalting at 24 and 26 prior to distillation. <IMAGE>

Description

SPECIFICATION A process and facility for upgrading heavy hydrocarbons employing a diluent The present invention relates to a process and facility for upgrading heavy hydrocarbonaceous materials, and more particularly, a process and facility for upgrading heavy crude oils generally characterized by high specific gravities, high pour points, high viscosities and high contents of sulfur, metals, water, salt and conradson carbon for making coke suitable for metallurgical purposes.

In the typical delayed coking process, residual oil is heated by exchanging heat with liquid products from the process and is fed into a fractionating tower wherein the light end products produced in the process or present in the residual oil are separated by distillation. The residual oil is then pumped from the base of the fractionating tower through a tubular furnace under pressure where it is heated to the required temperature and discharged into the bottom of the coke drum. The first stages of thermal decomposition reduce this residual oil to volatile products and a very heavy tar or pitch which further decomposes to yield solid coke particles.

The vapors formed during the decomposition produce pores and channels in the coke and pitch mass through which the incoming residual oil from the furnace must pass. The incoming oil and decomposition vapors serve to agitate and maintain the coke mass and residual oil mixture at relatively uniform temperature. This decomposition process is continued until the coke drum is filled with a mass of coke with a small amount of pitch. The vapors formed leave the top of the coke drum and are returned to the fractionating tower where they are fractionated into the desired petroleum cuts. After the coke drum is filled with a mixture of coke particles and some tar, residual vapors are removed, and the coke is removed from the drum by hydraulic or mechanical means.This green delayed petroleum coke has particular crystalline and chemical properties which make it especially suitable for making carbon anodes for the aluminum industry, but the green coke must be calcined or carbonized by further treatment to produce a finished calcined coke product.

Due to the characteristics of the heavy crude oils of the type set forth above they cannot be processed economically by conventional processing. In addition to their low quality these crude oils are extremely temperature sensitive and decompose at relatively low temperatures.

The processing and treatment of these crude oils at conventional conditions and in typical refining processes results in higher operating costs and the production of products which are predominantly of little value.

Naturally, it is highly desirable to provide a process and facility for upgrading heavy crude oils so as to allow for the economic production of valuable petroleum products. The process and facility of the present invention should allow for the economic production of coke suitable for metallurgical purposes.

Accordingly, it is a principal object of the present invention to provide a process and facility for upgrading heavy crude oils.

It is a particular object of the present invention to provide a process and facility for upgrading heavy crude oils for use in the production of metallurgical coke.

It is a further object of the present invention to provide a process and facility for upgrading heavy crude oils wherein a hydrocarbon diluent is employed to facilitate control of temperature and residence time thereby prohibiting premature decomposition.

It is a still further object of the present invention to provide a process and facility for upgrading heavy crude oils wherein the crude oil is carefully fractionated to maximize liquid yields during the coking step.

Further objects and advantages of the present invention wiil appear hereinbelow.

In accordance with the present invention the foregoing objects and advantages are readily obtained.

The present invention relates to a process and facility for upgrading heavy hydrocarbonaceous materials, and more particularly a process and facility for upgrading heavy crude oils for making coke suitable for metallurgical purposes. The crude oils found in Orinoco Oil Belt of Venezuela are generally characterized in high gravities (close to that of water); high pour points (solid at ambient temperatures); high viscosities; high metals, sulfur, water, salt and conradson carbon contents. In addition, the crude oils are extremely temperature sensitive, that is they easily decompose at low temperatures. The process and facility of the present invention allows for the economic production of petroleum products of upgraded value such as LPG, gasoline, kerosene, jet fuel, diesel oil and gas oils.

The process and facility employs the use of a hydrocarbon diluent with a closely controlled boiling range to facilitate transport, dehydration and desalting of the crude oil. Further, the diluent facilitates close control of temperatures and residence times thus avoiding premature decomposition and therewith degradation of coker yields. The process and facility also uses a coker fractionator and coker heater design intended to better control the quantity and quality of the coker recycle stream to minimize gas and coke formation and improve the density of the produced coke. The process and facility utilizes a careful fractionation of the crude oil for front end control to maximize liquid yields in the coking step.

The Figure is a schematic flow diagram illustrating the process and facility of the present invention.

The facility 10 and process of the present invention as shown in the drawing depicts the various stages of a delayed coke pilot plant including the facility for upgrading heavy crude oil feedstocks. A typical heavy crude oil feedstock from the Orinoco Oil Belt has the following composition and properties: Table I Gravity OKAPI 8.0(1,014 Kg/ms) Sulfur, % wt 3.71 Mercaptans, wt ppm Nil Pour Point, OF 80 Nitrogen, % wt 0.60 Water and Sediments, % Vol 6.4 Salt Content as NaCI, Lbs/1 000 BBls. 500 Conradson Carbon, % wt 13.8 H2S,wtppm 37 Neutralization Number, mgr KOH/gr 3.95 MNI, % wt 13.54 Asphaltenes, % wt 7.95 UOP K Factor 11.3 Viscosities:: KV at 1800F,cst 1184 KV at 1400F,cst 7558 KV at 1220F,cst 19229 MetalxContent: Iron, wt ppm 19 Vanadium, wt ppm 396 Nickel, wt ppm 78 Most of the oils fall within the following composition and properties: Table II Gravity, OKAPI 6-12 Viscosities: KV at 1800 F, cst 400-2500 KV at 1400F,cst 2000-20000 KV at 122"F, cst 5000-40000 Metal Content:: Iron, wt ppm 1 5-25 Vanadium, wt ppm 300-500 Nickel, wt ppm 60-120 Asphaltenes, % wt 6-12 Salt Content as NaCI, Lbs/1000 BBls. 35-1000 Pour Point, OF 50-90 Sulfur, % wt 3.5-4.5 Water and Sediments, % Vol 0.2-10 The crude feedstock is supplied to the facility shown in the Figure via line 12. The heavy crude oil is mixed with a diluent at the production well and later at the facility the crude is mixed with additional diluent delivered to line 1 2 by way of primary line 14, recycled diluent line 16 and line 18. The use of the diluent is critical for a number of reasons.Firstly, the diluent lowers the viscosity and pour point of the crude so that it is not solid at room temperature thereby facilitating transport of the crude. Secondly, the diluent aids in controlling the temperatures and residence times in the facility thereby avoiding premature decomposition and therewith degradation of coker yields. The diluent should be mixed with the crude oil in an amount of from about 10 to about 50 percent volume. In accordance with the present invention, the diluent should be a narrow boiling hydrocarbon diluent having suitable solubility characteristics so as to avoid separation.

The composition and properties of the diluent should fall within the following ranges: Table Ill Gracity, OKAPI 20-65 Viscosities: KV at 1000F,cst 0.5-10.5 KVat2100F,cst 0.1-3 Distillation ASTM D-86 (OF) JBP 150-410 50% Vol 200-610 EP 250-800 A diluent having the following composition and properties is preferred:: Table IV Gravity, OKAPI 35.4 Sulfur, % wt 0.48 Pour Point, OF -25 Water and Sediments, % Vol 0.02 Conradson Carbon, % wt 0.05 KVat 1000F,cst 3.35 KV at 1220F,cst 2.78 Distillation ASTM D-86 (OF) IBP 360 50% Vol 496 EP 642 The incoming feedstock from line 12, which is mixed with diluent from line 18, is fed to a desalting station 20 comprising in series a dehydrator 22 and a first and second stage desalter 24 and 26, respectively. The water content of the crude oil is reduced in dehydrator 22 down to about 1.0 volume percent and the salt content is reduced in the dehydrator to about 1 50 PTB, and in the desalters 24 and 26 down to about 5 PTB. The temperature in the desalting station 20 should not exceed 2750F.

The desalted crude oil flows from desalter 26 to fired heater 28 where the crude is preheated to its desired crude tower feed inlet temperature and from there to atmospheric pressure oil distillation unit 30 where it is separated into gases, liquid products and atmospheric residuum. The atmospheric distillation unit 30 is designed for several modes of operation.

In one operation, 5000F plus residuum is produced and is drawn off and fed via line 32 to combination tower 34 for use as cokerfeed. The 5000F minus overhead is drawn off through line 36 to splitter tower 38. The off gases from the atmospheric distillation unit 30 are removed through line 40 and passed to a gas scrubber of conventional design. The gas oil products from atmospheric distillation unit 30 are drawn off through line 42. The 5000F minus overhead is fed to splitter tower 38 where naphtha and off gases are separated out as overhead products and drawn off through lines 44 and 45, respectively. The splitter tower products is a narrow boiling 4000F-5000F liquid having properties and composition suitable for use as the diluent.The splitter bottom product is drawn off through line 1 6 and is recycled and mixed with the crude oil feedstock entering dehydrator 22.

In another mode of operation of atmospheric distillation unit 30, the unit will again produce a 5000F minus overhead product which is drawn off and fed to splitter tower 38 via line 36. A 5000F to 7000F gas oil is produced and removed through line 42. The atmospheric residuum is a 7000F plus product which is drawn off through line 32 to line 48 where it is fed to gas fired heater 50 when the atmospheric residuum is heated to its desired temperature and from there to vacuum distillation unit 52 for further processing. The atmospheric residuum is vacuum distilled in distillation unit 52 to produce a vaporized gas oil product which is drawn off through line 54 which may be recovered separately or combined with gas oil from the atmospheric unit 30. The vent gases from the vacuum distillation unit 52 are removed through line 56 and combined with the off gases from the atmospheric unit 30.The vacuum distillation unit is designed to produce from the atmospheric residue 9000F plus vacuum residuum which is drawn off through line 58 and fed to combination tower 34 for use as a coker feed via line 32.

The reduced crude coker feed from either of the above modes of operation is fed via line 32 to combination tower 34. Combination tower 34 comprises a heat transfer portion and a fractionator portion. The coker fresh feed from the atmospheric residuum or vacuum residuum flows via line 32 to the bottom section of combination tower 34 where it is heated by direct contact with coker effluent and fractionated to produce a reduced coker feed mixed with recycle.Coker feedstock is withdrawn from the bottom portion of combination tower 34 via line 60 and flows to coker heater 62 where the feedstock is heated to the desired temperature of about 9200 F. The coker feedstock is heated as it passes through coker heater 62 and is fed via line 64 to one of several delayed coking drums, either coke drum 66 or coke drum 58, where the hydrocarbon feedstock decomposes leaving a mass of green coke. The coke drum vapor containing coker products and recycle is drawn off through line 70 and flows to the fractionation portion of combination tower 34. The recycle is condensed and mixed with the fresh feed in the bottom section of tower 34 while the coker products are fractionated into off gas, coker naphtha, coker distillate and coker gas.The above fractionated coker products are drawn off via lines 72, 74, 76 and 78, respectively. The unit is designed to operate normally with a recycle ratio of 0.1.

However, if necessary the recycle ratio may be increased to 1.0 with a small reduction in fresh feed.

After sufficient coke is deposited in one coke drum, for example coke drum 66, the flow of the coker heater feedstock is switched to another coke drum 68 which has been preheated. The coke in coke drum 68 is then removed. The coke bed in the full drum is steam stripped and then cooled by water quenching. After draining of the water, the top and bottom heads of the drum are removed. The coke is then removed by hydraulic cutting and collected in a coke pit. Coke cutting water drained from the coke pit is collected through sluiceway and is pumped to storage tank for reuse. The empty druni is then reheated, steam purged and pressure tested. It is then reheated with superheated steam to about 700F and ready to receive the coking heater effluent again.

The coker liquid products may be further processed by hydrogenation to produce final products such as LPG, gasoline, kerosene, jet fuel, diesel oils and gas oils.

It is to be understood that the invention is not limited to the illustrations described and shown herein, which are deemed to be merely illustrative of the best modes of carrying oút the invention, and which are susceptible of modification of form, size, arrangement of parts and details of operation. The invention rather is intended to encompass all such modifications which are within its spirit and scope as defined by the

Claims (14)

claims. Claims

1. A process for upgrading heavy crude oils for making coke suitable for metallurgical purposes comprising: (a) mixing a diluent with incoming heavy crude oil so as to form a mixture of crude oil and diluent; (b) subjecting the mixture of crude oil and diluent to distillation whereby gas hydro carbon products, an overhead liquid hydrocarbon product and a residuum are produced; (c) subjecting said overhead liquid hydro carbon product to further treatment whereby naphtha and off gases are separated out as overhead products and a narrow boiling point diluent as produced; (d) recycling said narrow boiling point diluent; and (e) mixing said narrow boiling point diluent with said incoming heavy crude oil.

2. A process according to claim 1 wherein said narrow boiling point diluent boils at a range of about between 1 500F and 8000F.

3. A process according to claim 2 including subjecting said mixture of crude oil and diluent to dehydration and desalting prior to subjecting said mixture to distillation.

4. A process according to claim 2 including preheating said mixture of crude oil and diluent prior to distillation.

5. A process according to claim 3 wherein the salt content of said mixture of crude oil and diluent is reduced down to about not more than 5 PTB.

6. A process according to claim 3 wherein the water content of said mixture of crude oil and diluent is reduced down to about not more than 1.0 volume percent.

7. A process according to claim 3 wherein desalting temperature is less than or equal to about 2750F.

8. A process according to claim 1 wherein said diluent is mixed with said crude oil in an amount of from about 10 to 50 volume percent.

9. A process according to claim 1 wherein said overhead liquid hydrocarbon product boils at a temperature of less then or equal to about 5000F.

1 0. A facility for upgrading heavy crude oils for making coke suitable for metallurgical purposes comprising: (a) means for mixing a diluent with incoming heavy crude oil so as to form a mixture of crude oil and diluent; (b) a distillation unit downstream of the means for mixing the diluent with incoming heavy crude for distilling said mixture into gas hydrocarbon products, an overhead liquid hydrocarbon product and a residuum product; (c) splitter means downstream of said distillation unit to further treat said over head liquid hydrocarbon product so as to obtain a narrow boiling point diluent; and (d) recirculating means for recirculating said narrow boiling point diluent to said means for mixing said narrow boiling point diluent with said incoming heavy crude oil.

11. A facility according to claim 10 wherein said narrow boiling point diluent boils at a range of about between 1 500F and 8000F.

12. A facility according to claim 11 including means for dehydrating and desalting said mixture of crude oil prior to subjecting said mixture to distillation.

1 3. A facility according to claim 11 including means for preheating said mixture of crude oil and diluent prior to distillation.

14. A facility according to claim 12 wherein the salt content of said mixture of crude oil and diluent is reduced by said means to dehydrate and desalt to about not more than 5 PTB.

1 5. A facility according to claim 12 wherein the water content of said mixture of crude oil and diluent is reduced by said means to dehydrate and desalt to about not more than 1.0 volume percent.

1 6. A facility according to claim 10 wherein said diluent is mixed with said crude oil in an amount from about 10 to 50 volume percent.

1 7. A facility according to claim 10 wherein said overhead liquid hydrocarbon product boils at a temperature of less than or equal to about 5000F.

1 8. A process substantially as herein described.

1 9. A facility substantiaily as herein described with reference to the accompanying drawings.