Uses of Hydrocracking

Uses of Hydrocracking azs2

In a refinery, hydrocracking complements catalytic cracking by taking on the more aromatic feedstocks that resist cracking, including the byproducts of FCC, such as light cycle oil (LCO). Hydrocracking can also be used to upgrade residual fractions using different reactor configurations and catalysts depending on the complexity of the upgrading tasks, as shown in Figure 7.12. As shown in Figure 7.13, for hydrocracking a relatively light feedstock (e.g., atmospheric residue), a fixed-bed configuration and relatively large-size catalyst particles can be used. In extreme cases with very heavy vacuum residue, an expanded bed configuration is used, in which very fine catalyst particles are entrained in the feed at high hydrogen pressures (high hydrogen/oil ratio). These extreme reaction conditions are necessary to prevent extensive coking on catalysts that could shut down the process. For intermediate cases, an ebullated (fluidized) bed configuration can be used, as shown in Figure 7.13.

In the United States, hydrocracking of LCO (from FCC) provides a large proportion of the diesel fuel production because straight-run LGO is a preferred stock for FCC to produce gasoline as the principal product. The major licensors of hydrocracking processes include Chevron, UOP, ExxonMobil Research and Engineering, BP, Shell, and BASF-IFP.

Configuration of hydrocracking process with respect to feed properties. See text alternative below

Figure 7.12. Configuration of hydrocracking process with respect to feed properties.

Hydrocracking Process

  • Single Stage
    • Hydrocracking only
      • single catalyst
      • low S, N feeds
      • Hydrotreatment, Hydrocracking
    • dual catalyst
      • high S&N
      • can be done with or without recycling
  • Two-Stage (separation of the products between stages 1 & 2)
    • HT & HC
      • dual catalyst
      • very high S + N feeds
    • HT & HC
      • triple catalyst
      • extremely high S, N, metal feed
Credit: Dr. Semih Eser © Penn State is licensed under CC BY-NC-SA 4.0
Hydrocracking of heavy residue. See text alternative below

Figure 7.13. Hydrocracking of heavy residua.

Residue Hydrocracking

  • increasing H/C for upgrading
  • atmospheric or vacuum distillation reside
Hydrocracking of heavy residua
Bed TypeCat. SizeParticles/cm3
Fixed1.5 - 3mm120
Ebullated 0.8 - 3mm 250
Expanded 0.002mm2.4x109
Credit: Dr. Semih Eser © Penn State is licensed under CC BY-NC-SA 4.0

Hydrocracking vs. Catalytic Cracking

Hydrocracking Vs. Catalytic Cracking
Catalytic Cracking - FCCHydrocracking

carbon rejection

endothermic

acid catalyst

more gas

more coke

hydrogen addition

exothermic

metal catalyst on acid support

less gas

less coke

costly process ($$$)

  • Hydrocracking involves C-C bond cleavage to produce lighter HC's
  • More liquid yield with HYDRCRC
  • More hydrogenated products
    • Cracking is less severe
    • Secondary cracking reactions are minimized by stabilization of active species by hydrogen
  • Hydrocracking is more flexible w.r.t. the feedstock
    • Refractory feedstocks (i.e. aromatics) can be processed
    • C-C bond breaking after saturation with hydrogen

Above, we compare catalytic cracking (FCC - a carbon rejection process) with hydrocracking (HYDRCRC) with respect to the major attributes of both projects. Clearly, in a flexible refinery with a wide range of crude oil feedstocks, both processes are needed for the optimum conversion of the crude oil into desirable refinery products.