Methods for regenerating a spent catalyst in a metal reactor are disclosed. Such methods may employ a step of chlorinating the spent catalyst, followed by decoking the chlorinated spent catalyst, and then fluorinating the de-coked catalyst.

The present disclosure is directed to the use of novel crystalline germanosilicate compositions in affecting a range of organic transformations. In particular, the crystalline germanosilicate compositions are extra-large-pore compositions, designated CIT-13 possessing 10- and 14-membered rings.

The present disclosure is directed to the use of novel crystalline germanosilicate compositions in affecting a range of organic transformations. In particular, the crystalline germanosilicate compositions are extra-large-pore compositions, designated CIT-13 possessing 10- and 14-membered rings.

A process for preparing a hierarchical zeolite catalyst for aromatization of C5-C9 alkane that provides high conversion percentage of precursor to yields and high aromatics selectivity, wherein said process comprises the following steps: (a) preparing a solution containing alumina compound, silica compound, and soft template; (b) subjecting the mixture obtained from step (a) to hydrothermal process at determined time and temperature to form said mixture into the hierarchical zeolite; (c) contacting the hierarchical zeolite obtained from step (b) with ammonium salt solution; and (d) contacting the hierarchical zeolite obtained from step (c) with gallium salt solution; wherein the soft template in step (a) is a quaternary phosphonium salt in which the mole ratio of the silica compound to the alumina compound in step (a) is in a range of 20 to 120 and the gallium salt in step (d) has gallium to zeolite ratio in a range of 0.5 to 5% by weight.

Methods for regenerating a spent catalyst in a metal reactor are disclosed. Such methods may employ a step of chlorinating the spent catalyst, followed by decoking the chlorinated spent catalyst, and then fluorinating the de-coked catalyst.

Methods for regenerating a spent catalyst are disclosed. Such methods may employ a step of chlorinating the spent catalyst in the gas phase, followed by decoking the chlorinated spent catalyst, and then fluorinating the de-coked catalyst in a fluorine-containing solution of a fluorine-containing compound.

A method for upgrading a naphtha feed includes passing the naphtha feed to an adsorption unit to produce at least a paraffin stream and an isoparaffin stream, wherein the isoparaffin stream comprises isoparaffins and aromatics. Passing the isoparaffin stream to an isoparaffin aromatization catalytic unit that contacts the isoparaffin stream with at least one aromatization catalyst produces aromatics from the isoparaffins thereby yielding an aromatization effluent. The at least one aromatization catalyst may comprise ZSM-5 zeolite. Benzene, toluene, and/or xylene (BTX) may be separated from the aromatization effluent by separating the aromatics effluent into a gas stream and a liquid stream in a gas/liquid separator, wherein the liquid stream contains BTX. Passing the liquid stream to a BTX-separation unit may produce a BTX stream and a recycle stream, wherein the BTX stream contains benzene, toluene, and/or xylene.

The invention relates to a process for producing a particulate, Si-bonded fluidized-bed catalyst having improved abrasion resistance, which comprises the steps I. provision of an aqueous suspension comprising zeolite particles, II. addition of a silicone resin mixture comprising one or more hydrolyzable silicone resin precondensates and mixing of the aqueous suspension and the silicone resin mixture, III. spray drying of the mixture obtained from step II, with the mixture being homogenized before spray drying, and IV. calcination of the spray-dried fluidized-bed catalyst obtained from step III,
and an Si-bonded fluidized-bed catalyst which can be produced by this process and also its use for the nonoxidative dehydroaromatization of C.sub.1-C.sub.4-aliphatics.

A method for upgrading a naphtha feed includes passing the naphtha feed to an adsorption unit to produce at least a paraffin stream and an isoparaffin stream, wherein the isoparaffin stream comprises isoparaffins and aromatics. Passing the isoparaffin stream to an isoparaffin aromatization catalytic unit that contacts the isoparaffin stream with at least one aromatization catalyst produces aromatics from the isoparaffins thereby yielding an aromatization effluent. The at least one aromatization catalyst may comprise ZSM-5 zeolite. Benzene, toluene, and/or xylene (BTX) may be separated from the aromatization effluent by separating the aromatics effluent into a gas stream and a liquid stream in a gas/liquid separator, wherein the liquid stream contains BTX. Passing the liquid stream to a BTX-separation unit may produce a BTX stream and a recycle stream, wherein the BTX stream contains benzene, toluene, and/or xylene.

The invention relates to a process for producing a particulate, Si-bonded fluidized-bed catalyst having improved abrasion resistance, which comprises the steps I. provision of an aqueous suspension comprising zeolite particles, II. addition of a silicone resin mixture comprising one or more hydrolyzable silicone resin precondensates and mixing of the aqueous suspension and the silicone resin mixture, III. spray drying of the mixture obtained from step II, with the mixture being homogenized before spray drying, and IV. calcination of the spray-dried fluidized-bed catalyst obtained from step III,
and an Si-bonded fluidized-bed catalyst which can be produced by this process and also its use for the nonoxidative dehydroaromatization of C.sub.1-C.sub.4-aliphatics.