Title of Invention	A ZEOLITE CATALYST FOR SKELETAL ISOMERISATION OF OLEFINS
Abstract	There is disclosed a method for the manufacture of a zeolite catalyst, said method comprising the steps of: a) preparing a gel mixture capable of forming crystalline material using a gel ripening pre-treatment step carried out by adding a source(s), such as herein described, of alkali or alkaline earth metal (M) selected from sodium, potassium, magnesium and calcium to water whereby Solution A is obtained, then a source(s), such as herein described, of an oxide of a tetravalent element (Y) selected from silicon and germanium is added to Solution A with continuous stirring whereby Solution B is obtained, then Solution C is prepared by adding a source of an oxide of a trivalent element (X) selected from aluminium and gallium to water and to the obtained mixture a directing agent (R) selected from pyrrolidine and diethanolamine is added, the thus obtained Solution C is added to Solution B to obtain a gel mixture, which is stirred, then sulphuric acid is added to adjust the pH to the range of 8.5 - 13.5 and the mixture is stirred, said mixture having a composition, in terms of molar ratios, within the following ranges; b) carrying out hydrothermal synthesis wherein said mixture from step a) is maintained at a temperature from 100°C to 250°C under dynamic mode of stirring until crystals of said material are formed, recovering the material; and c) removing the directing agent (R) partly or totally with a stepwise calcination procedure, wherein the temperature of the zeolite product obtained from step b) is raised to an intermediate temperature of 200°C - 400°C followed by raising the temperature to a final calcination temperature of 400°C - 600°C and a zeolite catalyst having MTT structure is obtained, which has the following XRD pattern:

Title of Invention

A ZEOLITE CATALYST FOR SKELETAL ISOMERISATION OF OLEFINS

Abstract

There is disclosed a method for the manufacture of a zeolite catalyst, said method comprising the steps of: a) preparing a gel mixture capable of forming crystalline material using a gel ripening pre-treatment step carried out by adding a source(s), such as herein described, of alkali or alkaline earth metal (M) selected from sodium, potassium, magnesium and calcium to water whereby Solution A is obtained, then a source(s), such as herein described, of an oxide of a tetravalent element (Y) selected from silicon and germanium is added to Solution A with continuous stirring whereby Solution B is obtained, then Solution C is prepared by adding a source of an oxide of a trivalent element (X) selected from aluminium and gallium to water and to the obtained mixture a directing agent (R) selected from pyrrolidine and diethanolamine is added, the thus obtained Solution C is added to Solution B to obtain a gel mixture, which is stirred, then sulphuric acid is added to adjust the pH to the range of 8.5 - 13.5 and the mixture is stirred, said mixture having a composition, in terms of molar ratios, within the following ranges; b) carrying out hydrothermal synthesis wherein said mixture from step a) is maintained at a temperature from 100°C to 250°C under dynamic mode of stirring until crystals of said material are formed, recovering the material; and c) removing the directing agent (R) partly or totally with a stepwise calcination procedure, wherein the temperature of the zeolite product obtained from step b) is raised to an intermediate temperature of 200°C - 400°C followed by raising the temperature to a final calcination temperature of 400°C - 600°C and a zeolite catalyst having MTT structure is obtained, which has the following XRD pattern:

Full Text	A ZEOLITE CATALYST FOR SKELETAL ISOMERISATION OF OLEFINS Field of Invention The present invention relates to an active zeolite catalyst having MTT structure and to a method for the manufacture of said catalyst. More particularly, the invention relates to a method for preparing the MTT structure whereby the synthesis is facilitated and reproducible, and the obtained product exhibits high catalytic utility. Said zeolite catalyst is particularly suitable for olefin isomerization reactions. Background of Invention Molecular sieves are an important class of inorganic materials used in catalysis. Zeolites are an essential group of molecular sieves. Zeolites are crystalline aluminosilicates with a well-defined pore structure. The International Zeolite Association recognized 136 different groups of framework in January 2003. MTT is one of the structural groups of zeolites. Four types of zeolites having MTT structure are known in the art: ZSM-23, EU-13, IS1-4 and KZ-1. ZSM-23 zeolite has one-dimensional 10-ring channels. The unit cell of ZSM-23 can be represented as: Na+n [Aln Si 24-n O48] ~ 4H20, n dimensions of the channel system are 0.45 x 0.52 nm [1], In general, various zeolites are prepared using hydrothermal synthesis. In principal three major variables influence on the zeolite structure crystallised and said variables are the composition of the reaction mixture, the template and the time. For example, patents US 3 702 886 and US 3 926 782 describe the synthesis of MFI-structure based zeolite ZSM-5, US 4 481 177 describes the synthesis of TON structure based zeolite 2SM-22, and US 4 016 245 describes the synthesis of FER structure based zeolite ZSM-35. Several publications describe different factors, which are important in zeolite synthesis. Rollmann et al. teaches about the role of small amines in zeolite synthesis [2]. The synthesis of high-silica zeolites with one-directional medium pore systems, by using nitrogen-free templates has been studied by Giordan et al. [3]. Moini et al. [4] describe the role of diquatemary cations as directing agents in zeolite synthesis. The present inventors have studied in detail the effect of synthesis time and mode of stining on physicochemical and catalytic properties of ZSM- 5 zeolite catalysts [5]. Several methods for preparation of MTT-structures are known. Patents US 4 076 842, US 4 104 151, GB 21 90910, GB 2 202 838, US 4 490 342, US 4531 012 and US 4 619820 describe the synthesis of ZSM-23 from reaction mixtures containing different amines as structure directing agents or templates. International patent applications WO 96/29285 and WO 96/29286 provide methods for the production of medium pore zeolites, including ZSM-23, in the absence of any nitrogen-containing templating agent other than the small neutral amine. US 5 332 566 teaches the formation of ZSM-23 with a templating agent having the formula C14H36N33+. US 6 099 820 discloses a method for making MTT zeolites without an organic template. EP 0 347 273 provides a method for the manufacture of a MTT type zeolite using fluorine containing compounds in the synthesis mixture. Isomerization is a hydrocarbon transformation reaction and it is catalyzed by acid sites. In an isomerization reaction, the molecular formula of one substance does not change but its structure changes. Isomerization can be divided into several groups after the group of molecules that are isomerized (paraffin isomerization, olefin isomerization, etc.), or alternatively it can also be divided after the reaction type (skeletal isomerization, double-bond isomerization, etc.). The term "skeletal isomerization" stands here for a reaction wherein one n-olefin reacts to a corresponding isoolefin. This reaction is also known as olefin isomerization, hydrocarbon conversion, preparation of branched olefins, conversion of normal olefins to branched olefins and structural isomerization. Several patents describe skeletal isomerization of olefins with zeolite catalysts, For example, in patents EP 0574 994, EP 0 523 838, US 5 491 296, US 5 510 560, US 6 323 384 and US 6 111 160 ferrierites are used in skeletal isomererization. ZSM-35 has a similar type of zeolite structure as ferrierite and its use in skeletal isomerization is discussed in US 5 449 851 and WO 94/08920. Other potential catalysts for skeletal isomerization of olefins are catalysts based on TON structure like ZSM-22. In patents US 5 157 194, US 523 7121 and EP 0 5 49 294 the use of ZSM-22 based catalysts in skeletal isomerization is described. MTT structure based catalysts, such as ZSM-23, are also used in skeletal isomerization of light olefins. In an example of US 5 243 090, HZSM-23 is used in n- butene conversion under a pressure of 720 kPa and. at temperatures between 551-554 °C. The conversion of n-butene was 38 % with 84 % selectivity to isobutene. In US 5 817 907, in examples 3 and 4, the uses of fresh and coked ZSM-23 catalysts in skeletal isomerization of n-butene are shown. The conversion of n-butene with the coked catalyst was 46 % with 40 % isobutene selectivity, and with the fresh catalyst, 52 % with 20 % isobutene selectivity, respectively. Recently, a summary of the performance of different zeolite catalysts used in the skeletal isomerization has been presented [6]. It was found that ZSM-5, ZSM-22 and ZSM-23 are less adequate for butene skeletal isomerizarion than ferrierite, due to structural characteristics and a less suitable acidity (Table 1). All the studied zeolite catalysts showed a limited activity to isoolefins and a fast deactivation in the olefin skeletal isomerization reaction. Table 1. Microporous catalysts and their properties in butene skeletal isomerization [6] In the light of the state of the art it can be seen that there is an evident need for a highly active and selective zeolite catalyst, which can be used in olefin isomerization reactions. Object of the Invention An object of the invention is to provide a method for the manufacture of an active and selective zeolite catalyst having MTT structure. A further objective of the invention is to provide a novel, active and selective zeolite catalyst having MTT structure. A further object of the invention is the use of the active and selective zeolite catalyst having MTT structure, particularly in olefin isomerization reactions. Characteristic features of the method for the manufacture of the active and selective zeolite catalyst having MTT structure, of the active and selective zeolite catalyst having MTT structure, and the use of the active and selective zeolite catalyst having MTT structure are provided in the claims. Summary of the invention It has now been found that the problems related to zeolite catalysts, which are used in olefin isomerization reactions, can be avoided or at least significantly decreased by the active and selective zeolite catalyst having MTT structure, prepared according to the invention. The MTT structure based catalyst comprises a carrier selected from alumina, silica or clay or any other carrier of the state of the art and possible combinations thereof. The amount of carrier varies between 10-90 wt-%, calculated on the total weight of the catalyst. The method for the manufacture of the novel zeolite catalyst having MTT structure comprises the following steps: a) Preparation of a gel mixture using a gel ripening pre-treatment step at ambient temperature, b) Hydrothermal synthesis in dynamic mode of stirring ("rotational" or "vigorous internal" stirring), and c) Removing of structure directing agent from the zeolite catalyst using a calcination procedure. The phase pure and highly crystalline zeolite catalysts having MTT structure, which are prepared according to the method of the invention, have superior selectivity and activity, particularly in skeletal isomerization of light olefins. Said catalysts provide essentially higher yields of isoolefins than the currently available catalysts according to the state of the art, presented in Table 1. Detailed description of the invention Without wishing to be restricted by the following explanations and theoretical considerations regarding the synthesis of the novel zeolite catalysts with MTT' structure, which are particularly suitable for olefin isomerization reactions, the essential features of the invention are discussed as follows. The method for the manufacture of a zeolite catalyst having MTT structure comprises: a) Preparing of a gel mixture capable of forming crystalline material, and said mixture comprising a source(s) of alkali or alkaline earth metal (M) selected from sodium, potassium, magnesium, calcium, a source(s) of an oxide of a trivalent element (X) selected from aluminium and gallium, a source(s) of an oxide of a tetravalent element (Y) selected from silicon and germanium, water and a directing agent (R) selected from compounds comprising organic nitrogen containing cations, preferably pyrrolidine and diethanolamme, and said mixture having a composition, in terms of molar ratios, within the following ranges of Table 2, wherein (O) is oxygen and (H) hydrogen; b) Carrying out hydrothermal synthesis wherein said mixture from step a) is maintained under sufficient conditions including a temperature from about 100 °C to about 250 °C under dynamic mode of stirring until crystals of said material are formed, recovering the material, and c) Removing of said directing agent (R) partly or totally from the material obtained in step b) with a calcination procedure, whereby a zeolite catalyst having MTT structure is obtained. A typical X-ray diffraction (XRD) pattern of a zeolite catalyst with MTT structure according to the invention is presented in Figure 1. No other zeolite as an impurity was observed. The X-ray diffraction pattern was collected with Siemens Daco-MP Kristalloflex instrument. The sample holder was mads of PVC. Figure 2, a scanning electron micrograph of a zeolite catalyst with MTT structure according to the invention, shows that the zeolite catalyst comprises small rod shaped crystals. The method for the manufacture of the zeolite catalyst having MTT structure, preferably comprises the following steps: a) Preparation of the gel mixture using a gel ripening pre-treatment step at ambient temperature, b) Carrying out the hydrothermal synthesis in dynamic mode of stirring ("rotational" or "vigorous internal" stirring), and c) Removing of the structure directing agent (R) partly or totally from the zeolite catalyst using a calcination procedure. The steps a), b) and c) are described in detail in the following: Step a): The preparation of a gel mixture using a gel ripening pre-treatment step is carried out as follows: Solution A is prepared by adding a source(s) of an oxide of an alkali or alkaline earth metal selected from sodium, potassium, magnesium and calcium, preferably sodium hydroxide, potassium hydroxide or sodium carbonate, to water, preferably ion exchanged or distilled water, and the obtained solution is stirred. A source(s) of an oxide of a tetravalent element selected from silicon and germanium, preferably colloidal silica, solid silica, fumed silica or silica hydroxide, is added to the above described Solution A with continuous stirring. After the addition of the oxide of the tetravalent element, the mixture is further stirred. This obtained mixture is denoted as Solution B. Solution C is prepared by adding a source(s) of an oxide of a trivalent element selected from aluminium and gallium, preferably aluminium sulphate (A12(S04)3.18H2O), hydrated aluminium hydroxides, aluminates, aluminium isoproxide and alumina, to water, preferably deiordzed or distilled water, and the mixture is further stirred. To this mixture, a directing agent (R) selected from compounds comprising organic nitrogen containing cations, preferably pyrrolidine or diethanolamine, is added, preferably dropwise, with vigorous stirring. After the addition of the directing agent, the mixture is further stirred. Solution C is added to Solution B slowly. After the addition of Solution C to Solution B, the obtained gel mixture is further stirred (gel ripening). To this gei mixture sulphuric acid is added slowly, keeping pH in an alkaline range, preferably in the range of 8.5-13.5. The gel mixture is further stirred (gel ripening). The use of gel ripening (gel ageing) provides nuclei necessary for the synthesis of comparatively uniform shape, size and distribution of the crystals of the zeolite having MTT structure. Gel ripening may also shorten the synthesis time (i.e. it can accelerate the crystallization process). Further, it may influence the yield of the zeolite with MTT structure and influence the Si/Al ratio. Step b): The hydrothermal synthesis in dynamic mode of stirring ("rotational" or "vigorous internal" stirring) is carried out as follows: The gel mixture prepared in step a) is charged into a reactor, which is optionally pressurized to a pressure between 02-5 Mpa. The strirring is started and the temperature of the reactor is raised to a temperature suitable for the crystallization, preferably to 100-250 °C and particularly preferably to 120-220 °C. The synthesis is carried out in a dynamic mode. The hydrothermal synthesis can be carried out in a heatable, stirred tank reactor, in a loop reactor, in an ebuuated reactor or in any other reactor suitable for solid-liquid phase reactions known in the state of the art. After the completion of the synthesis, the temperature of the reactor is decreased rapidly. The product is isolated, washed with water, preferably deionised or distilled water, and dried. The hydrothermal synthesis is carried out in a dynamic mode (i.e. rotation or vigorous internal stirring during synthesis). This mode of stirring is known from the state of the art to influence phase purity and size of crystals of aluminosilicate type of zeolites, and if static mode i.e. without stirring is used, larger crystals are obtained when compared with preparation under continuous stirring. The use of dynamic mode of stirring in the synthesis of the zeolite with MTT structure results in zeolitic material with high crystallinity, phase purity and crystals with regular size. Step c): Removal of the structure directing agent from the zeolite catalyst is carried out using a calcination procedure as follows: The calcination procedure is performed by raising the temperature of an oven or other suitable heatable equipment containing the zeolite obtained from step b) with a slow heating rate, preferably 0.05-2 °C/min to a temperature of 400-600 °C. Preferably a slow heating rate is applied to reach an intermediate temperature of 200-400 °C, which is then followed by raising the temperature to the final calcination temperature of 400-600 °C. The removal of the structure directing agent i.e. the organic template, is carried out by the calcination procedure. The removal of the stiructure directing agent after the completion of the synthesis of the zeolite catalyst is an important step in order to free its pores of organic compounds to obtain high surface area. Temperature, heating rate, duration of calcinations and presence of carrier gas during organic template removal from MTT structure may influence surface area, pore systems, location of framework alumina and formation of extraframework alumina. The method optionally comprises replacing ions of the crystalline material, at least in part, by ion exchange with an ion or a mixture of ions selected from the group consisting of hydrogen and hydrogen precursors or metals. The zeolite catalyst having MTT structure contains a carrier selected from alumina, silica or clay or any other carrier of the state of the art and possible combinations thereof. The amount of the carrier varies between 10-90 wt-%, calculated on the amount of the catalyst. The catalyst can be formulated with techniques known in the art, such as spray drying, extrusion and the like. The zeolite catalyst having MTT structure according to the invention can be modified using any conventional methods known in the art. Examples of such methods are calcination procedures, ion exchange procedures, impregnation procedures and various other treatments known in the art. The different steps in the manufacture of the catalyst according to the invention can be performed in any suitable equipment generally known in the art. The novel zeolite catalysts having MTT structure showed surprisingly high activities and selectivities, particularly in skeletal isomerization of light olefins. Additionally, no deactivation was observed in conditions where commercial catalysts were rapidly deactivated, as can be seen from Example 9. The zeolite catalyst having MTT structure may be used in skeletal isotnerization processes of olefins, suitably in fixed bed reactors and in fluidised bed reactors. In the process, a feed containing at least one group of olefins having 4 to 20, preferably from 4 to 10 carbon atoms, is brought into contact with the catalyst at a temperature between 50 oC and 500 °C, depending on the olefin which is isomerized, and under a pressure between 0.01 and 5 MPa. Particularly suitable feed comprises C4, C5, C6 or C7 oleEnic hydrocarbons, or mixtures thereof, preferably G4, C5 or C6 olefmic hydrocarbons. The isomerization process can be carried out in a packed bed reactor, a fixed bed reactor, fluidized bed reactor or a moving bed reactor. Especially preferred reactor system is described in FI patent 101156 and patent application FI 20002783, the contents of which are incorporated by reference herein. The invention is illustrated in detail with the following examples. However, the scope of the invention is not meant to be limited to the examples. Examples Example 1 Preparation of a zeolite catalyst having MTT structure Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of distilled water and stirred. 33.5 g of fumed silica was added to Solution A with continuous stirring. After the addition of the fumed silica, the solution was further stirred. This mixture was denoted as Solution B. Solution C was prepared by adding 3.9 g of aluminium sulphate ((Al2(SO4)3.18H2O) to 49.2 g of distilled water and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added dropwise with vigorous stirring speed. After the addition of pyrrolidine, the mixture was further stirred. Solution C was added slowly to Solution B. After the addition of Solution C to Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0 g of sulphuric acid was added slowly. The prepared gel mixture was further stirred {gel ripening). Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature of the oven was raised to 180 °C. The synthesis was carried out in dynamic mode for 48 hours at 180 °C. After the completion of the synthesis the autoclaves were quenched. The product was mixed with distilled water, filtered and washed with on- line flowing distilled water. The product was left to dry over a filter paper. The crystalline product was separated from the filter paper and dried over a ceramic dish in an oven with airflow. The temperature and time of drying were 110 °C for 12 h, respectively. Step c): The calcination procedure was performed stepwise by raising the temperature of the muffle oven containing the zeolite sample (slow heating rate) to an intermediate temperature. The calcination was carried out at the intermediate temperature for an interval of time, followed by raising the temperature (slow heating rate) to the final calcination temperature below 600 °C where the zeolite was calcined. The properties of the obtained product were the following: The Si/Al-ratio was 42, the amount of Bronsted acid sites was 90 μmol/g, the sodium content was 0.1 wt-%, the carbon content was 0.7 wt-% and the BET-surfaoe area was 110 m2/g. The XRD- diffraction pattern is given in Table 3. Example 2 Ion-exchange procedure The sodium form of the zeolite catalyst having MTT structure, obtained from example 1, was transformed to proton form by repeated ion-exchange method using aqueous solutions of ammonium chloride. After the ion-exchange procedure, the ammonium form of the zeolite was washed thoroughly with distilled water. The ammonium form of the zeolite was dried at 100 °C for 10 h and it was transformed into proton form using the stepwise calcination procedure. The properties of the obtained product (New catalyst A) were the following: The SiA1-ratio was 42, the amount of Bronsted acid sites was 170 μmol/g and the sodium content was 92 ppm. Example 3 Preparation of a zeolite catalyst having MTT etructure Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of distilled water and the mixture was stirred. 33.5 g of filmed silica was added to Solution A with continuous stirring. After the addition of fumed silica, the solution was former stirred. This mixture was denoted as Solution B. Solution C was prepared by adding 3.9 g of aluminium sulphate (Al2(SO4)3.18H2O) to 49.2 g of distilled water and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added dropwise with vigorous stirring speed. After the addition of pyrrolidine, the mixture was further stirred. Solution C was added slowly to Solution B. After the addition of Solution C to Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0 g of sulphuric acid was added slowly. The prepared, gel mixture was further stirred (gel ripening). Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature of the oven was raised to 180 °C. The synthesis was carried out in dynamic mode at 180°C for 24h. After the completion of the synthesis, the autoclaves were quenched. The product was mixed with distilled water, filtered and washed with on-line flowing distilled water. The product was left to dry over a filter paper. The crystalline product was separated from the filter paper and dried over a ceramic dish in an oven with airflow. The temperature and time of drying were 110 °C for 12 h, respectively. Step c): The calcination procedure was performed stepwise by raising the temperature of the muffle oven containing the zeolite sample (slow heating rate) to an intermediate temperature. The calcination was carried out at the intermediate temperature for an interval of time, followed by raising the temperature (slow heating rate) to the final calcination temperature below 600 °C where the zeolite was calcined. Example 4 Ion-exchange procedure The sodium form of the zeolite catalyst having MTT structure, obtained from example 3, was transformed to proton form by a repeated ion-exchange method using aqueous solutions of ammonium nitrate. After the ion-exchange procedure, the ammonium form of the zeolite was washed thoroughly with distilled water. The ammonium form of zeolite was dried at 100 °C for 10 h and it was transformed into proton form by calcination. Example 5 Preparation of a zeolite catalyst having MTT structure Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of distilled water and the mixture was stirred 33.5 g of fumed silica was added to Solution A with continuous stirring. After the addition of fumed silica, the solution was further stirred. This mixture was denoted as Solution B. Solution C was prepared by adding 3.9 g of aluminium sulphate (Al2(SO4)3.18H2O) to 49.2 g of distilled water and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added with vigorous stirring speed. After the addition of pyrrolidine, the mixture was further stirred. Solution C was added to Solution B slowly. After the addition of the Solution C to Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0 g of sulphuric acid was added slowly. The prepared gel mixture was further stirred (gel ripening). Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature of the oven was raised to 180 °C. The synthesis was tarried out in dynamic mode at 180 °C for 96 h. After the completion of the synthesis, the autoclaves were quenched. The product was mixed with distilled water, filtered and washed with on-line flowing distilled water. The product was left to dry over a filter paper. The crystalline product was separated from the filter paper and dried over a ceramic dish in an oven with airflow. The temperature and time of drying were 110 oC for 12 h, respectively. Step c): The step calcination procedure was performed by raising the temperature of the muffle oven containing the zeolite sample (slow heating rate) to an intermediate temperature. The calcination was carried out at the intermediate temperature for an interval of time, followed by raising the temperature (slow heating rate) to the final calcination temperature below 600 °C where the zeolite was calcinated. The stepwise calcination procedure of the zeolite catalyst with MTT structure resulted in the removal of the organic template. Example 6 Ion-exchange procedure The sodium form of the zeolite catalyst having MTT structure, obtained from example 5, was transformed to proton form by repeated ion-exchange method using aqueous solutions of ammonium nitrate. After the ion-exchange procedure, the ammonium form of the zeolite was washed thoroughly with distilled water. The ammonium form of zeolite was dried at 100 °C for 10 h and it was transformed into proton form by calcination. Example 7 Preparation of zeolite catalyst having MTT structure Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of distilled water and the mixture was stirred. 33.5 g of fumed silica was added to Solution A with a continuous stirring. After the addition of fumed silica, it was further stirred. This mixture is denoted as Solution B. Solution C was prepared by adding 3.9 g of aluminium sulphate (A12(SO4)3.18H2O) to 49.2 g of distilled water and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added dropwise with vigorous stirring speed. After the addition of pyrrolidine the mixture was further stirred. Solution C was slowly added to Solution B. After the addition of Solution C to Solution B the gel mixture was farther stirred (gel ripening). To this gel mixture 8.0 g of sulphuric acid was added slowly. The prepared gel. mixture was further stirred, (gel ripening). Step b): The prepared gel mixture was put in a teflon cup inserted in a 300 ml steel autoclave. The autoclave was mounted over a shaft in an oven and the temperature of the oven was raised to 180 °C. The synthesis was carried out under vigorous stirring for 48 hours at 180 °C. After completion of the synthesis, the autoclave was quenched. The product was mixed with distilled water, filtered and washed with on-line flowing distilled water. The sample was left to dry over a filter paper. The crystalline product was separated from the filter paper and dried over a ceramic dish in an oven with airflow. The temperature and time of drying was 110 °C for 12 h, respectively. The product was calcinated for template removal. Example 8 Ion-exchange procedure The sodium form of the zeolite catalyst having MTI structure from example 7 was transformed to proton form by repeated ion-exchange method using aqueous solutions of ammonium nitrate. After the ion-exchange, the ammonium form of zeolite was washed thoroughly with distilled water. The ammonium form of zeolite was dried at 100 °C for 10 h and transformed into proton form by calcination. The obtained product was denoted "New catalyst B". Example 9 Skeletal isomerization with a zeolite catalyst having MTT structure A catalyst having a MTT structure (ZSM-23) was prepared according to the method described in Example 2 (New catalyst A). The activity was compared to those of the ferrierite type and ZSM-22 type catalysts in a fixed bed microreactor. Ferrierite A was a ferrierite catalyst without any carrier, ferrierite B was a ferrierite catalyst with alumina carrier and ferrierite C was a ferrierite catalyst with clay carrier. The feed contained 40 wt-% of n-hexane and 60 wt-% of n-hexenes. The tests were made at 225 °C, 1 bar and with weight hourly space velocity (WHSV) of 20 1/h. Total run times were 48 hours. The yield of isohexenes (conversion of n-hexenes x selectivity to isohexenes) was determined from on-line GC-analysis of product samples. Figure 3 shows the yields obtained with different catalysts as a function of time on stream. The yield of isohexenes was noticeably higher with the catalyst according to the invention having the MTT-structure than with ferrierite or ZSM-22 catalysts. In addition, no deactivation was observed with the catalyst of the invention. Example 10 Skeletal isomerkation with a zeolite catalyst having MTT structure The activity of a catalyst having a MTT structure, prepared according to the method described in Example 8 (New catalyst B), was compared to that of the ferrierite catalyst A with n-pentene feed. n-Pentenes were diluted with 50 wt-% n-pentane. The catalysts were tested in a microreactor at 225 °C, 1 bar and with WHSV of 40 h"1. Table 4 shows that the yield of isopentenes was higher with ZSM-23 (New catalyst B) than with the commercial ferrierite A after 25 hours on stream. The conversion of n-pentenes was noticeably higher with ZSM-23 (New catalyst B) than with the ferrierite A. The lower selectivity to isopentenes with the New catalyst B was related to the higher conversion level obtained. Table 4. The activities with New catalyst B and with commercial ferrierite A after 25 hours on stream Example 11 Skeletal isomerization of 1-butene with a zeolite catalyst having MTT structure The activity of a catalyst having MTT-structure (New catalyst A), prepared according to Example 2, was tested in skeletal isomerization of 1-butene at 400 °C and under atmospheric pressure. The activity was compared to that of commercial ferrierite A and ZSM-22. n-Butene feed with WHSV of 44 h-1 was used. The results in Table 5 show that at similar conversion level, the selectivity to isobutene was higher with the New catalyst A than with other catalysts. Table 5. The selectivity to isobutene with the new catalyst A, with commercial ferrierite A and with ZSM-22 Example 12 Skeletal isomerization of n-hexenes The activity of the catalyst prepared according to Example 8 (New catalyst B) was tested in skeletal isomerization of n-hexenes at 225 °C and 1 bar. In addition, the catalyst from Example 7 was calcined the same way as the catalyst in Example 8, but no ion-exchange was performed. This yielded New catalyst C. The activity of the New catalyst C was similar to that of the New catalyst B (Figure 4). Ion exchange was, thus, not needed for the catalyst to be active under the used conditions. Example 13 (Comparative example) Skeletal isomerization of hezene with a SSM-23 zeolite catalyst A ZSM-23 catalyst was prepared as instructed in US 4 076 842. The activity of the ZSM-23 catalyst was studied in a fixed bed reactor. The test conditions were exactly the same as in Example 9. The obtained conversion of n-hexene was significantly low, being 1 wt-% or even lower. References: 1. www.iza-online.org 2. On the role of small amines in zeolite synthesis, Rollmann, L. D., Schelenker, J. L. Lawton, S. L., Kennedy, C. L. Kennedy, G. J. Doren, D. J., J.Phys.Chem, B 103 (34) (1999) 7175. 3. Synthesis of high-cilica zeolites with unidirectional medium pores systems using nitrogen free templates, Giordano, G., Di Renzo, F., Remoue, F., Fajula, F., Plee, D., Schulz, P., Stud. Surf. Sci. Cat. 84 (1994) 141. 4. The role of diquaternary cations as directing agents in zeolite synthesis, Moini, A., Schmitt, K. D., Valyocsik, E. W., Polomski, R. F., Stud. Surf. Sci. Cat. 84 (1994) 23. 5. Effect of synthesis time and mode of stirring on the physico-chemical and catalytic properties of ZSM-5 zeolite catalysts, Kumar, N., Nieminen, V., Demirkan, K., Salmi, T., Murzin, D. Yu., Laine, E., Appl. Catal. A: General 235 (2002) 113. 6. Deactivation of solid acid catalyst for butene skeletal isomerization: on the beneficial and harmful effects of carbonaceous desposits, van Donk, S., Bitter, J., de Jong, K., Appl. Catal. A: General 212 (2001) 97. WE CLAIM: 1. A method for the manufacture of a zeolite catalyst, said method comprising the steps of: a) preparing a gel mixture capable of forming crystalline material using a gel ripening pre-treatment step carried out by adding a source(s), such as herein described, of alkali or alkaline earth metal (M) selected from sodium, potassium, magnesium and calcium to water whereby Solution A is obtained, then a source (s), such as herein described, of an oxide of a tetravalent element (Y) selected from silicon and germanium is added to Solution A with continuous stirring whereby Solution B is obtained, then Solution C is prepared by adding a source of an oxide of a trivalent element (X) selected from aluminium and gallium to water and to the obtained mixture a directing agent (R) selected from pyrrolidine and diethanolamine is added, the thus obtained Solution C is added to Solution B to obtain a gel mixture, which is stirred, then sulphuric acid is added to adjust the pH to the range of 8.5 - 13.5 and the mixture is stirred, said mixture having a composition, in terms of molar ratios, within the following ranges; b) carrying out hydrothermal synthesis wherein said mixture from step a) is maintained at a temperature from 100°C to 250°C under dynamic mode of stirring until crystals of said material are formed, recovering the material; and c) removing the directing agent (R) partly or totally with a stepwise calcination procedure, wherein the temperature of the zeolite product obtained from step b) is raised to an intermediate temperature of 200°C - 400°C followed by raising the temperature to a final calcination temperature of 400°C - 600°C and a zeolite catalyst having MTT structure is obtained, which has the following XRD pattern: 2. The method as claimed in claim 1, for the manufacture of a zeolite catalyst, wherein the source of an alkali or alkaline earth metal (M) is sodium hydroxide, potassium hydroxide or sodium carbonate, the source of an oxide of a trivalent element (X) is aluminium sulphate, hydrated aluminium hydroxides, aluminates, aluminium isoproxide or alumina and the source of an oxide of a tetravalent element (Y) is colloidal silica, solid silica, fumed silica or silica hydroxide. 3. The method as claimed in claim 1 or 2 for the manufacture of a zeolite catalyst, wherein, in step b) the hydrotherma! synthesis is carried out at a temperature of 100-250 °C, preferably at 120°- 220°C, the gel mixture prepared in step a) is charged into a reactor, and after the completion of the synthesis, the reactor is cooled, the product is isolated, washed with water, and dried. 4. The method as claimed in any one of claims 1 no 3, for the manufacture of a zeolite catalyst, which involves: replacing ions of the crystalline material, at least in part, by ion exchange with an ion or a mixture of ions selected from the group consisting of hydrogen and hydrogen precursors or metals. 5. A zeolite catalyst, wherein the zeolite catalyst has MTT structure and the following XRD pattern: 6. A zeolite catalyst according to claim 5, which comprises 10-90 wt-% of a carrier selected from alumina, silica or clay and combinations thereof. 7. A method for skeletal isomerization of olefins, wherein skeletal isomerization of a feed comprising olefinic hydrocarbons containing from 4 to 20, preferably from 4 to 10 carbon atoms is carried out in the presence of a zeolite catalyst as claimed in claim 5 or 6, or that manufactured according to the method as claimed in any one of claims 1-4. 8. The method as claimed in claim 7, for skeletal isomerization of olefins, wherein the temperature maintained is 40°-500°C and the pressure maintained is 0.1-5 MPa and the skeletal isomerization is carried out in a fixed bed reactor or in a fluidized bed reactor. 9. The method as claimed in claim 7 or 8, for skeletal isomerization of olefins, wherein the feed is olefinic C4 feed. 10. The method as claimed in 7 or 8, for skeletal isomerization of olefins, wherein the feed is olefinic C5 feed. 11. A method as claimed in claim 7 or 8, for skeletal isomerization of olefins, wherein the feed is olefinic C6 feed. There is disclosed a method for the manufacture of a zeolite catalyst, said method comprising the steps of: a) preparing a gel mixture capable of forming crystalline material using a gel ripening pre-treatment step carried out by adding a source(s), such as herein described, of alkali or alkaline earth metal (M) selected from sodium, potassium, magnesium and calcium to water whereby Solution A is obtained, then a source(s), such as herein described, of an oxide of a tetravalent element (Y) selected from silicon and germanium is added to Solution A with continuous stirring whereby Solution B is obtained, then Solution C is prepared by adding a source of an oxide of a trivalent element (X) selected from aluminium and gallium to water and to the obtained mixture a directing agent (R) selected from pyrrolidine and diethanolamine is added, the thus obtained Solution C is added to Solution B to obtain a gel mixture, which is stirred, then sulphuric acid is added to adjust the pH to the range of 8.5 - 13.5 and the mixture is stirred, said mixture having a composition, in terms of molar ratios, within the following ranges; b) carrying out hydrothermal synthesis wherein said mixture from step a) is maintained at a temperature from 100°C to 250°C under dynamic mode of stirring until crystals of said material are formed, recovering the material; and c) removing the directing agent (R) partly or totally with a stepwise calcination procedure, wherein the temperature of the zeolite product obtained from step b) is raised to an intermediate temperature of 200°C - 400°C followed by raising the temperature to a final calcination temperature of 400°C - 600°C and a zeolite catalyst having MTT structure is obtained, which has the following XRD pattern:

Full Text

A ZEOLITE CATALYST FOR SKELETAL ISOMERISATION OF OLEFINS
Field of Invention
The present invention relates to an active zeolite catalyst having MTT structure and to
a method for the manufacture of said catalyst. More particularly, the invention relates
to a method for preparing the MTT structure whereby the synthesis is facilitated and
reproducible, and the obtained product exhibits high catalytic utility. Said zeolite
catalyst is particularly suitable for olefin isomerization reactions.
Background of Invention
Molecular sieves are an important class of inorganic materials used in catalysis.
Zeolites are an essential group of molecular sieves. Zeolites are crystalline
aluminosilicates with a well-defined pore structure. The International Zeolite
Association recognized 136 different groups of framework in January 2003. MTT is
one of the structural groups of zeolites.
Four types of zeolites having MTT structure are known in the art: ZSM-23, EU-13,
IS1-4 and KZ-1. ZSM-23 zeolite has one-dimensional 10-ring channels. The unit cell
of ZSM-23 can be represented as: Na+n [Aln Si 24-n O48] ~ 4H20, n dimensions of the channel system are 0.45 x 0.52 nm [1],
In general, various zeolites are prepared using hydrothermal synthesis. In principal
three major variables influence on the zeolite structure crystallised and said variables
are the composition of the reaction mixture, the template and the time. For example,
patents US 3 702 886 and US 3 926 782 describe the synthesis of MFI-structure
based zeolite ZSM-5, US 4 481 177 describes the synthesis of TON structure based

zeolite 2SM-22, and US 4 016 245 describes the synthesis of FER structure based
zeolite ZSM-35.
Several publications describe different factors, which are important in zeolite
synthesis. Rollmann et al. teaches about the role of small amines in zeolite synthesis
[2]. The synthesis of high-silica zeolites with one-directional medium pore systems,
by using nitrogen-free templates has been studied by Giordan et al. [3]. Moini et al.
[4] describe the role of diquatemary cations as directing agents in zeolite synthesis.
The present inventors have studied in detail the effect of synthesis time and mode of
stining on physicochemical and catalytic properties of ZSM- 5 zeolite catalysts [5].
Several methods for preparation of MTT-structures are known. Patents US 4 076 842,
US 4 104 151, GB 21 90910, GB 2 202 838, US 4 490 342, US 4531 012 and US 4
619820 describe the synthesis of ZSM-23 from reaction mixtures containing different
amines as structure directing agents or templates. International patent applications
WO 96/29285 and WO 96/29286 provide methods for the production of medium pore
zeolites, including ZSM-23, in the absence of any nitrogen-containing templating
agent other than the small neutral amine. US 5 332 566 teaches the formation of
ZSM-23 with a templating agent having the formula C14H36N33+. US 6 099 820
discloses a method for making MTT zeolites without an organic template. EP 0 347
273 provides a method for the manufacture of a MTT type zeolite using fluorine
containing compounds in the synthesis mixture.
Isomerization is a hydrocarbon transformation reaction and it is catalyzed by acid
sites. In an isomerization reaction, the molecular formula of one substance does not
change but its structure changes. Isomerization can be divided into several groups
after the group of molecules that are isomerized (paraffin isomerization, olefin
isomerization, etc.), or alternatively it can also be divided after the reaction type
(skeletal isomerization, double-bond isomerization, etc.).

The term "skeletal isomerization" stands here for a reaction wherein one n-olefin
reacts to a corresponding isoolefin. This reaction is also known as olefin
isomerization, hydrocarbon conversion, preparation of branched olefins, conversion
of normal olefins to branched olefins and structural isomerization.
Several patents describe skeletal isomerization of olefins with zeolite catalysts, For
example, in patents EP 0574 994, EP 0 523 838, US 5 491 296, US 5 510 560, US 6
323 384 and US 6 111 160 ferrierites are used in skeletal isomererization. ZSM-35
has a similar type of zeolite structure as ferrierite and its use in skeletal isomerization
is discussed in US 5 449 851 and WO 94/08920.
Other potential catalysts for skeletal isomerization of olefins are catalysts based on
TON structure like ZSM-22. In patents US 5 157 194, US 523 7121 and EP 0 5 49
294 the use of ZSM-22 based catalysts in skeletal isomerization is described.
MTT structure based catalysts, such as ZSM-23, are also used in skeletal
isomerization of light olefins. In an example of US 5 243 090, HZSM-23 is used in n-
butene conversion under a pressure of 720 kPa and. at temperatures between 551-554
°C. The conversion of n-butene was 38 % with 84 % selectivity to isobutene. In US 5
817 907, in examples 3 and 4, the uses of fresh and coked ZSM-23 catalysts in
skeletal isomerization of n-butene are shown. The conversion of n-butene with the
coked catalyst was 46 % with 40 % isobutene selectivity, and with the fresh catalyst,
52 % with 20 % isobutene selectivity, respectively.
Recently, a summary of the performance of different zeolite catalysts used in the
skeletal isomerization has been presented [6]. It was found that ZSM-5, ZSM-22 and
ZSM-23 are less adequate for butene skeletal isomerizarion than ferrierite, due to
structural characteristics and a less suitable acidity (Table 1). All the studied zeolite

catalysts showed a limited activity to isoolefins and a fast deactivation in the olefin
skeletal isomerization reaction.
Table 1. Microporous catalysts and their properties in butene skeletal
isomerization [6]

In the light of the state of the art it can be seen that there is an evident need for a
highly active and selective zeolite catalyst, which can be used in olefin isomerization
reactions.
Object of the Invention
An object of the invention is to provide a method for the manufacture of an active and
selective zeolite catalyst having MTT structure.
A further objective of the invention is to provide a novel, active and selective zeolite
catalyst having MTT structure.

A further object of the invention is the use of the active and selective zeolite catalyst
having MTT structure, particularly in olefin isomerization reactions.
Characteristic features of the method for the manufacture of the active and selective
zeolite catalyst having MTT structure, of the active and selective zeolite catalyst
having MTT structure, and the use of the active and selective zeolite catalyst having
MTT structure are provided in the claims.
Summary of the invention
It has now been found that the problems related to zeolite catalysts, which are used in
olefin isomerization reactions, can be avoided or at least significantly decreased by
the active and selective zeolite catalyst having MTT structure, prepared according to
the invention.
The MTT structure based catalyst comprises a carrier selected from alumina, silica or
clay or any other carrier of the state of the art and possible combinations thereof. The
amount of carrier varies between 10-90 wt-%, calculated on the total weight of the
catalyst.
The method for the manufacture of the novel zeolite catalyst having MTT structure
comprises the following steps:
a) Preparation of a gel mixture using a gel ripening pre-treatment step at ambient
temperature,
b) Hydrothermal synthesis in dynamic mode of stirring ("rotational" or "vigorous
internal" stirring), and

c) Removing of structure directing agent from the zeolite catalyst using a calcination
procedure.
The phase pure and highly crystalline zeolite catalysts having MTT structure, which
are prepared according to the method of the invention, have superior selectivity and
activity, particularly in skeletal isomerization of light olefins. Said catalysts provide
essentially higher yields of isoolefins than the currently available catalysts according
to the state of the art, presented in Table 1.
Detailed description of the invention
Without wishing to be restricted by the following explanations and theoretical
considerations regarding the synthesis of the novel zeolite catalysts with MTT'
structure, which are particularly suitable for olefin isomerization reactions, the
essential features of the invention are discussed as follows.
The method for the manufacture of a zeolite catalyst having MTT structure
comprises:
a) Preparing of a gel mixture capable of forming crystalline material, and
said mixture comprising a source(s) of alkali or alkaline earth metal (M)
selected from sodium, potassium, magnesium, calcium, a source(s) of an
oxide of a trivalent element (X) selected from aluminium and gallium, a
source(s) of an oxide of a tetravalent element (Y) selected from silicon
and germanium, water and a directing agent (R) selected from compounds
comprising organic nitrogen containing cations, preferably pyrrolidine and
diethanolamme, and said mixture having a composition, in terms of molar
ratios, within the following ranges of Table 2, wherein (O) is oxygen and
(H) hydrogen;

b) Carrying out hydrothermal synthesis wherein said mixture from step a) is
maintained under sufficient conditions including a temperature from about
100 °C to about 250 °C under dynamic mode of stirring until crystals of said
material are formed, recovering the material, and
c) Removing of said directing agent (R) partly or totally from the material
obtained in step b) with a calcination procedure, whereby a zeolite catalyst
having MTT structure is obtained.
A typical X-ray diffraction (XRD) pattern of a zeolite catalyst with MTT structure
according to the invention is presented in Figure 1. No other zeolite as an impurity
was observed. The X-ray diffraction pattern was collected with Siemens Daco-MP
Kristalloflex instrument. The sample holder was mads of PVC.
Figure 2, a scanning electron micrograph of a zeolite catalyst with MTT structure
according to the invention, shows that the zeolite catalyst comprises small rod shaped
crystals.

The method for the manufacture of the zeolite catalyst having MTT structure,
preferably comprises the following steps:
a) Preparation of the gel mixture using a gel ripening pre-treatment step at
ambient temperature,
b) Carrying out the hydrothermal synthesis in dynamic mode of stirring
("rotational" or "vigorous internal" stirring), and
c) Removing of the structure directing agent (R) partly or totally from the zeolite
catalyst using a calcination procedure.
The steps a), b) and c) are described in detail in the following:
Step a): The preparation of a gel mixture using a gel ripening pre-treatment step is
carried out as follows: Solution A is prepared by adding a source(s) of an oxide of an
alkali or alkaline earth metal selected from sodium, potassium, magnesium and
calcium, preferably sodium hydroxide, potassium hydroxide or sodium carbonate, to
water, preferably ion exchanged or distilled water, and the obtained solution is stirred.
A source(s) of an oxide of a tetravalent element selected from silicon and germanium,
preferably colloidal silica, solid silica, fumed silica or silica hydroxide, is added to
the above described Solution A with continuous stirring. After the addition of the
oxide of the tetravalent element, the mixture is further stirred. This obtained mixture
is denoted as Solution B.
Solution C is prepared by adding a source(s) of an oxide of a trivalent element
selected from aluminium and gallium, preferably aluminium sulphate
(A12(S04)3.18H2O), hydrated aluminium hydroxides, aluminates, aluminium

isoproxide and alumina, to water, preferably deiordzed or distilled water, and the
mixture is further stirred. To this mixture, a directing agent (R) selected from
compounds comprising organic nitrogen containing cations, preferably pyrrolidine or
diethanolamine, is added, preferably dropwise, with vigorous stirring. After the
addition of the directing agent, the mixture is further stirred.
Solution C is added to Solution B slowly. After the addition of Solution C to Solution
B, the obtained gel mixture is further stirred (gel ripening). To this gei mixture
sulphuric acid is added slowly, keeping pH in an alkaline range, preferably in the
range of 8.5-13.5. The gel mixture is further stirred (gel ripening).
The use of gel ripening (gel ageing) provides nuclei necessary for the synthesis of
comparatively uniform shape, size and distribution of the crystals of the zeolite
having MTT structure. Gel ripening may also shorten the synthesis time (i.e. it can
accelerate the crystallization process). Further, it may influence the yield of the
zeolite with MTT structure and influence the Si/Al ratio.
Step b): The hydrothermal synthesis in dynamic mode of stirring ("rotational" or
"vigorous internal" stirring) is carried out as follows: The gel mixture prepared in
step a) is charged into a reactor, which is optionally pressurized to a pressure between
02-5 Mpa. The strirring is started and the temperature of the reactor is raised to a
temperature suitable for the crystallization, preferably to 100-250 °C and particularly
preferably to 120-220 °C. The synthesis is carried out in a dynamic mode. The
hydrothermal synthesis can be carried out in a heatable, stirred tank reactor, in a loop
reactor, in an ebuuated reactor or in any other reactor suitable for solid-liquid phase
reactions known in the state of the art.

After the completion of the synthesis, the temperature of the reactor is decreased
rapidly. The product is isolated, washed with water, preferably deionised or distilled
water, and dried.
The hydrothermal synthesis is carried out in a dynamic mode (i.e. rotation or
vigorous internal stirring during synthesis). This mode of stirring is known from the
state of the art to influence phase purity and size of crystals of aluminosilicate type of
zeolites, and if static mode i.e. without stirring is used, larger crystals are obtained
when compared with preparation under continuous stirring. The use of dynamic mode
of stirring in the synthesis of the zeolite with MTT structure results in zeolitic
material with high crystallinity, phase purity and crystals with regular size.
Step c): Removal of the structure directing agent from the zeolite catalyst is carried
out using a calcination procedure as follows:
The calcination procedure is performed by raising the temperature of an oven or other
suitable heatable equipment containing the zeolite obtained from step b) with a slow
heating rate, preferably 0.05-2 °C/min to a temperature of 400-600 °C. Preferably a
slow heating rate is applied to reach an intermediate temperature of 200-400 °C,
which is then followed by raising the temperature to the final calcination temperature
of 400-600 °C.
The removal of the structure directing agent i.e. the organic template, is carried out by
the calcination procedure. The removal of the stiructure directing agent after the
completion of the synthesis of the zeolite catalyst is an important step in order to free
its pores of organic compounds to obtain high surface area. Temperature, heating rate,
duration of calcinations and presence of carrier gas during organic template removal

from MTT structure may influence surface area, pore systems, location of framework
alumina and formation of extraframework alumina.
The method optionally comprises replacing ions of the crystalline material, at least in
part, by ion exchange with an ion or a mixture of ions selected from the group
consisting of hydrogen and hydrogen precursors or metals.
The zeolite catalyst having MTT structure contains a carrier selected from alumina,
silica or clay or any other carrier of the state of the art and possible combinations
thereof. The amount of the carrier varies between 10-90 wt-%, calculated on the
amount of the catalyst.
The catalyst can be formulated with techniques known in the art, such as spray
drying, extrusion and the like.
The zeolite catalyst having MTT structure according to the invention can be modified
using any conventional methods known in the art. Examples of such methods are
calcination procedures, ion exchange procedures, impregnation procedures and
various other treatments known in the art.
The different steps in the manufacture of the catalyst according to the invention can
be performed in any suitable equipment generally known in the art.
The novel zeolite catalysts having MTT structure showed surprisingly high activities
and selectivities, particularly in skeletal isomerization of light olefins. Additionally,
no deactivation was observed in conditions where commercial catalysts were rapidly
deactivated, as can be seen from Example 9.

The zeolite catalyst having MTT structure may be used in skeletal isotnerization
processes of olefins, suitably in fixed bed reactors and in fluidised bed reactors. In the
process, a feed containing at least one group of olefins having 4 to 20, preferably
from 4 to 10 carbon atoms, is brought into contact with the catalyst at a temperature
between 50 oC and 500 °C, depending on the olefin which is isomerized, and under a
pressure between 0.01 and 5 MPa. Particularly suitable feed comprises C4, C5, C6 or
C7 oleEnic hydrocarbons, or mixtures thereof, preferably G4, C5 or C6 olefmic
hydrocarbons.
The isomerization process can be carried out in a packed bed reactor, a fixed bed
reactor, fluidized bed reactor or a moving bed reactor. Especially preferred reactor
system is described in FI patent 101156 and patent application FI 20002783, the

contents of which are incorporated by reference herein.
The invention is illustrated in detail with the following examples. However, the scope
of the invention is not meant to be limited to the examples.
Examples
Example 1
Preparation of a zeolite catalyst having MTT structure
Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of
distilled water and stirred. 33.5 g of fumed silica was added to Solution A with
continuous stirring. After the addition of the fumed silica, the solution was further
stirred. This mixture was denoted as Solution B. Solution C was prepared by adding
3.9 g of aluminium sulphate ((Al2(SO4)3.18H2O) to 49.2 g of distilled water and the
mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added

dropwise with vigorous stirring speed. After the addition of pyrrolidine, the mixture
was further stirred.
Solution C was added slowly to Solution B. After the addition of Solution C to
Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0
g of sulphuric acid was added slowly. The prepared gel mixture was further stirred
{gel ripening).
Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel
autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature
of the oven was raised to 180 °C. The synthesis was carried out in dynamic mode for
48 hours at 180 °C. After the completion of the synthesis the autoclaves were
quenched. The product was mixed with distilled water, filtered and washed with on-
line flowing distilled water. The product was left to dry over a filter paper. The
crystalline product was separated from the filter paper and dried over a ceramic dish
in an oven with airflow. The temperature and time of drying were 110 °C for 12 h,
respectively.
Step c): The calcination procedure was performed stepwise by raising the temperature
of the muffle oven containing the zeolite sample (slow heating rate) to an
intermediate temperature. The calcination was carried out at the intermediate
temperature for an interval of time, followed by raising the temperature (slow heating
rate) to the final calcination temperature below 600 °C where the zeolite was
calcined.
The properties of the obtained product were the following: The Si/Al-ratio was 42,
the amount of Bronsted acid sites was 90 μmol/g, the sodium content was 0.1 wt-%,

the carbon content was 0.7 wt-% and the BET-surfaoe area was 110 m2/g. The XRD-
diffraction pattern is given in Table 3.

Example 2
Ion-exchange procedure
The sodium form of the zeolite catalyst having MTT structure, obtained from
example 1, was transformed to proton form by repeated ion-exchange method using
aqueous solutions of ammonium chloride. After the ion-exchange procedure, the
ammonium form of the zeolite was washed thoroughly with distilled water. The
ammonium form of the zeolite was dried at 100 °C for 10 h and it was transformed
into proton form using the stepwise calcination procedure. The properties of the
obtained product (New catalyst A) were the following: The SiA1-ratio was 42, the
amount of Bronsted acid sites was 170 μmol/g and the sodium content was 92 ppm.

Example 3
Preparation of a zeolite catalyst having MTT etructure
Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of
distilled water and the mixture was stirred. 33.5 g of filmed silica was added to
Solution A with continuous stirring. After the addition of fumed silica, the solution
was former stirred. This mixture was denoted as Solution B. Solution C was prepared
by adding 3.9 g of aluminium sulphate (Al2(SO4)3.18H2O) to 49.2 g of distilled water
and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added
dropwise with vigorous stirring speed. After the addition of pyrrolidine, the mixture
was further stirred.
Solution C was added slowly to Solution B. After the addition of Solution C to
Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0
g of sulphuric acid was added slowly. The prepared, gel mixture was further stirred
(gel ripening).
Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel
autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature
of the oven was raised to 180 °C. The synthesis was carried out in dynamic mode at
180°C for 24h.
After the completion of the synthesis, the autoclaves were quenched. The product was
mixed with distilled water, filtered and washed with on-line flowing distilled water.
The product was left to dry over a filter paper. The crystalline product was separated
from the filter paper and dried over a ceramic dish in an oven with airflow. The
temperature and time of drying were 110 °C for 12 h, respectively.

Step c): The calcination procedure was performed stepwise by raising the temperature
of the muffle oven containing the zeolite sample (slow heating rate) to an
intermediate temperature. The calcination was carried out at the intermediate
temperature for an interval of time, followed by raising the temperature (slow heating
rate) to the final calcination temperature below 600 °C where the zeolite was
calcined.
Example 4
Ion-exchange procedure
The sodium form of the zeolite catalyst having MTT structure, obtained from
example 3, was transformed to proton form by a repeated ion-exchange method using
aqueous solutions of ammonium nitrate. After the ion-exchange procedure, the
ammonium form of the zeolite was washed thoroughly with distilled water. The
ammonium form of zeolite was dried at 100 °C for 10 h and it was transformed into
proton form by calcination.
Example 5
Preparation of a zeolite catalyst having MTT structure
Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of
distilled water and the mixture was stirred 33.5 g of fumed silica was added to
Solution A with continuous stirring. After the addition of fumed silica, the solution
was further stirred. This mixture was denoted as Solution B. Solution C was prepared
by adding 3.9 g of aluminium sulphate (Al2(SO4)3.18H2O) to 49.2 g of distilled water
and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added
with vigorous stirring speed. After the addition of pyrrolidine, the mixture was further
stirred.

Solution C was added to Solution B slowly. After the addition of the Solution C to
Solution B, the gel mixture was further stirred (gel ripening). To this gel mixture 8.0
g of sulphuric acid was added slowly. The prepared gel mixture was further stirred
(gel ripening).
Step b): The prepared gel mixture was put in two teflon cups inserted in 300 ml steel
autoclaves. The autoclaves were mounted over a shaft in an oven and the temperature
of the oven was raised to 180 °C. The synthesis was tarried out in dynamic mode at
180 °C for 96 h. After the completion of the synthesis, the autoclaves were quenched.
The product was mixed with distilled water, filtered and washed with on-line flowing
distilled water. The product was left to dry over a filter paper. The crystalline product
was separated from the filter paper and dried over a ceramic dish in an oven with
airflow. The temperature and time of drying were 110 oC for 12 h, respectively.
Step c): The step calcination procedure was performed by raising the temperature of
the muffle oven containing the zeolite sample (slow heating rate) to an intermediate
temperature. The calcination was carried out at the intermediate temperature for an
interval of time, followed by raising the temperature (slow heating rate) to the final
calcination temperature below 600 °C where the zeolite was calcinated. The stepwise
calcination procedure of the zeolite catalyst with MTT structure resulted in the
removal of the organic template.
Example 6
Ion-exchange procedure
The sodium form of the zeolite catalyst having MTT structure, obtained from
example 5, was transformed to proton form by repeated ion-exchange method using
aqueous solutions of ammonium nitrate. After the ion-exchange procedure, the

ammonium form of the zeolite was washed thoroughly with distilled water. The
ammonium form of zeolite was dried at 100 °C for 10 h and it was transformed into
proton form by calcination.
Example 7
Preparation of zeolite catalyst having MTT structure
Step a): Solution A was prepared by adding 8.9 g of sodium hydroxide to 392 g of
distilled water and the mixture was stirred. 33.5 g of fumed silica was added to
Solution A with a continuous stirring. After the addition of fumed silica, it was
further stirred. This mixture is denoted as Solution B. Solution C was prepared by
adding 3.9 g of aluminium sulphate (A12(SO4)3.18H2O) to 49.2 g of distilled water
and the mixture was further stirred. To this mixture, 17.9 g of pyrrolidine was added
dropwise with vigorous stirring speed. After the addition of pyrrolidine the mixture
was further stirred.
Solution C was slowly added to Solution B. After the addition of Solution C to
Solution B the gel mixture was farther stirred (gel ripening). To this gel mixture 8.0 g
of sulphuric acid was added slowly. The prepared gel. mixture was further stirred, (gel
ripening).
Step b): The prepared gel mixture was put in a teflon cup inserted in a 300 ml steel
autoclave. The autoclave was mounted over a shaft in an oven and the temperature of
the oven was raised to 180 °C. The synthesis was carried out under vigorous stirring
for 48 hours at 180 °C.
After completion of the synthesis, the autoclave was quenched. The product was
mixed with distilled water, filtered and washed with on-line flowing distilled water.

The sample was left to dry over a filter paper. The crystalline product was separated
from the filter paper and dried over a ceramic dish in an oven with airflow. The
temperature and time of drying was 110 °C for 12 h, respectively. The product was
calcinated for template removal.
Example 8
Ion-exchange procedure
The sodium form of the zeolite catalyst having MTI structure from example 7 was
transformed to proton form by repeated ion-exchange method using aqueous
solutions of ammonium nitrate. After the ion-exchange, the ammonium form of
zeolite was washed thoroughly with distilled water. The ammonium form of zeolite
was dried at 100 °C for 10 h and transformed into proton form by calcination. The
obtained product was denoted "New catalyst B".
Example 9
Skeletal isomerization with a zeolite catalyst having MTT structure
A catalyst having a MTT structure (ZSM-23) was prepared according to the method
described in Example 2 (New catalyst A). The activity was compared to those of the
ferrierite type and ZSM-22 type catalysts in a fixed bed microreactor. Ferrierite A
was a ferrierite catalyst without any carrier, ferrierite B was a ferrierite catalyst with
alumina carrier and ferrierite C was a ferrierite catalyst with clay carrier. The feed
contained 40 wt-% of n-hexane and 60 wt-% of n-hexenes. The tests were made at
225 °C, 1 bar and with weight hourly space velocity (WHSV) of 20 1/h. Total run
times were 48 hours. The yield of isohexenes (conversion of n-hexenes x selectivity
to isohexenes) was determined from on-line GC-analysis of product samples.

Figure 3 shows the yields obtained with different catalysts as a function of time on
stream. The yield of isohexenes was noticeably higher with the catalyst according to
the invention having the MTT-structure than with ferrierite or ZSM-22 catalysts. In
addition, no deactivation was observed with the catalyst of the invention.
Example 10
Skeletal isomerkation with a zeolite catalyst having MTT structure
The activity of a catalyst having a MTT structure, prepared according to the method
described in Example 8 (New catalyst B), was compared to that of the ferrierite
catalyst A with n-pentene feed. n-Pentenes were diluted with 50 wt-% n-pentane. The
catalysts were tested in a microreactor at 225 °C, 1 bar and with WHSV of 40 h"1.
Table 4 shows that the yield of isopentenes was higher with ZSM-23 (New catalyst
B) than with the commercial ferrierite A after 25 hours on stream. The conversion of
n-pentenes was noticeably higher with ZSM-23 (New catalyst B) than with the
ferrierite A. The lower selectivity to isopentenes with the New catalyst B was related
to the higher conversion level obtained.
Table 4. The activities with New catalyst B and with commercial ferrierite A after 25
hours on stream

Example 11
Skeletal isomerization of 1-butene with a zeolite catalyst having MTT structure
The activity of a catalyst having MTT-structure (New catalyst A), prepared according
to Example 2, was tested in skeletal isomerization of 1-butene at 400 °C and under
atmospheric pressure. The activity was compared to that of commercial ferrierite A
and ZSM-22. n-Butene feed with WHSV of 44 h-1 was used. The results in Table 5
show that at similar conversion level, the selectivity to isobutene was higher with the
New catalyst A than with other catalysts.
Table 5. The selectivity to isobutene with the new catalyst A, with commercial
ferrierite A and with ZSM-22

Example 12
Skeletal isomerization of n-hexenes
The activity of the catalyst prepared according to Example 8 (New catalyst B) was
tested in skeletal isomerization of n-hexenes at 225 °C and 1 bar. In addition, the
catalyst from Example 7 was calcined the same way as the catalyst in Example 8, but
no ion-exchange was performed. This yielded New catalyst C. The activity of the
New catalyst C was similar to that of the New catalyst B (Figure 4). Ion exchange
was, thus, not needed for the catalyst to be active under the used conditions.

Example 13 (Comparative example)
Skeletal isomerization of hezene with a SSM-23 zeolite catalyst
A ZSM-23 catalyst was prepared as instructed in US 4 076 842. The activity of the
ZSM-23 catalyst was studied in a fixed bed reactor. The test conditions were exactly
the same as in Example 9. The obtained conversion of n-hexene was significantly
low, being 1 wt-% or even lower.

References:
1. www.iza-online.org
2. On the role of small amines in zeolite synthesis, Rollmann, L. D., Schelenker, J.
L. Lawton, S. L., Kennedy, C. L. Kennedy, G. J. Doren, D. J., J.Phys.Chem, B
103 (34) (1999) 7175.
3. Synthesis of high-cilica zeolites with unidirectional medium pores systems using
nitrogen free templates, Giordano, G., Di Renzo, F., Remoue, F., Fajula, F., Plee,
D., Schulz, P., Stud. Surf. Sci. Cat. 84 (1994) 141.
4. The role of diquaternary cations as directing agents in zeolite synthesis, Moini,
A., Schmitt, K. D., Valyocsik, E. W., Polomski, R. F., Stud. Surf. Sci. Cat. 84
(1994) 23.

5. Effect of synthesis time and mode of stirring on the physico-chemical and
catalytic properties of ZSM-5 zeolite catalysts, Kumar, N., Nieminen, V.,
Demirkan, K., Salmi, T., Murzin, D. Yu., Laine, E., Appl. Catal. A: General 235
(2002) 113.
6. Deactivation of solid acid catalyst for butene skeletal isomerization: on the
beneficial and harmful effects of carbonaceous desposits, van Donk, S., Bitter, J.,
de Jong, K., Appl. Catal. A: General 212 (2001) 97.

WE CLAIM:
1. A method for the manufacture of a zeolite catalyst, said method comprising the
steps of:
a) preparing a gel mixture capable of forming crystalline material using a gel
ripening pre-treatment step carried out by adding a source(s), such as herein
described, of alkali or alkaline earth metal (M) selected from sodium, potassium,
magnesium and calcium to water whereby Solution A is obtained, then a source
(s), such as herein described, of an oxide of a tetravalent element (Y) selected
from silicon and germanium is added to Solution A with continuous stirring
whereby Solution B is obtained, then Solution C is prepared by adding a source of
an oxide of a trivalent element (X) selected from aluminium and gallium to water
and to the obtained mixture a directing agent (R) selected from pyrrolidine and
diethanolamine is added, the thus obtained Solution C is added to Solution B to
obtain a gel mixture, which is stirred, then sulphuric acid is added to adjust the pH
to the range of 8.5 - 13.5 and the mixture is stirred, said mixture having a
composition, in terms of molar ratios, within the following ranges;

b) carrying out hydrothermal synthesis wherein said mixture from step a) is
maintained at a temperature from 100°C to 250°C under dynamic mode of stirring
until crystals of said material are formed, recovering the material; and
c) removing the directing agent (R) partly or totally with a stepwise calcination
procedure, wherein the temperature of the zeolite product obtained from step b) is
raised to an intermediate temperature of 200°C - 400°C followed by raising the
temperature to a final calcination temperature of 400°C - 600°C and a zeolite
catalyst having MTT structure is obtained, which has the following XRD pattern:

2. The method as claimed in claim 1, for the manufacture of a zeolite
catalyst, wherein the source of an alkali or alkaline earth metal (M) is sodium
hydroxide, potassium hydroxide or sodium carbonate, the source of an oxide of a
trivalent element (X) is aluminium sulphate, hydrated aluminium hydroxides,
aluminates, aluminium isoproxide or alumina and the source of an oxide of a
tetravalent element (Y) is colloidal silica, solid silica, fumed silica or silica
hydroxide.
3. The method as claimed in claim 1 or 2 for the manufacture of a zeolite
catalyst, wherein, in step b) the hydrotherma! synthesis is carried out at a
temperature of 100-250 °C, preferably at 120°- 220°C, the gel mixture prepared
in step a) is charged into a reactor, and after the completion of the synthesis, the
reactor is cooled, the product is isolated, washed with water, and dried.
4. The method as claimed in any one of claims 1 no 3, for the manufacture of a
zeolite catalyst, which involves: replacing ions of the crystalline material, at least
in part, by ion exchange with an ion or a mixture of ions selected from the group
consisting of hydrogen and hydrogen precursors or metals.
5. A zeolite catalyst, wherein the zeolite catalyst has MTT structure and the
following XRD pattern:

6. A zeolite catalyst according to claim 5, which comprises 10-90 wt-% of a
carrier selected from alumina, silica or clay and combinations thereof.
7. A method for skeletal isomerization of olefins, wherein skeletal
isomerization of a feed comprising olefinic hydrocarbons containing from 4 to 20,
preferably from 4 to 10 carbon atoms is carried out in the presence of a zeolite
catalyst as claimed in claim 5 or 6, or that manufactured according to the method
as claimed in any one of claims 1-4.
8. The method as claimed in claim 7, for skeletal isomerization of olefins,
wherein the temperature maintained is 40°-500°C and the pressure maintained is
0.1-5 MPa and the skeletal isomerization is carried out in a fixed bed reactor or in
a fluidized bed reactor.
9. The method as claimed in claim 7 or 8, for skeletal isomerization of
olefins, wherein the feed is olefinic C4 feed.
10. The method as claimed in 7 or 8, for skeletal isomerization of olefins,
wherein the feed is olefinic C5 feed.
11. A method as claimed in claim 7 or 8, for skeletal isomerization of olefins,
wherein the feed is olefinic C6 feed.

There is disclosed a method for the manufacture of a zeolite catalyst, said method
comprising the steps of:
a) preparing a gel mixture capable of forming crystalline material using a gel ripening
pre-treatment step carried out by adding a source(s), such as herein described, of alkali or
alkaline earth metal (M) selected from sodium, potassium, magnesium and calcium to water
whereby Solution A is obtained, then a source(s), such as herein described, of an oxide of a
tetravalent element (Y) selected from silicon and germanium is added to Solution A with
continuous stirring whereby Solution B is obtained, then Solution C is prepared by adding a
source of an oxide of a trivalent element (X) selected from aluminium and gallium to water and
to the obtained mixture a directing agent (R) selected from pyrrolidine and diethanolamine is
added, the thus obtained Solution C is added to Solution B to obtain a gel mixture, which is
stirred, then sulphuric acid is added to adjust the pH to the range of 8.5 - 13.5 and the mixture is
stirred, said mixture having a composition, in terms of molar ratios, within the following ranges;

b) carrying out hydrothermal synthesis wherein said mixture from step a) is maintained at a
temperature from 100°C to 250°C under dynamic mode of stirring until crystals of said material
are formed, recovering the material; and
c) removing the directing agent (R) partly or totally with a stepwise calcination procedure,
wherein the temperature of the zeolite product obtained from step b) is raised to an intermediate
temperature of 200°C - 400°C followed by raising the temperature to a final calcination
temperature of 400°C - 600°C and a zeolite catalyst having MTT structure is obtained, which has
the following XRD pattern:

Documents:

1742-KOLNP-2005-CORRESPONDENCE 1.1.pdf

1742-KOLNP-2005-CORRESPONDENCE.pdf

1742-KOLNP-2005-FOR ALTERATION OF ENTRY.pdf

1742-KOLNP-2005-FORM 27-1.1.pdf

1742-KOLNP-2005-FORM 27.pdf

1742-KOLNP-2005-FORM-27.pdf

1742-kolnp-2005-granted-abstract.pdf

1742-kolnp-2005-granted-assignment.pdf

1742-kolnp-2005-granted-claims.pdf

1742-kolnp-2005-granted-correspondence.pdf

1742-kolnp-2005-granted-description (complete).pdf

1742-kolnp-2005-granted-drawings.pdf

1742-kolnp-2005-granted-examination report.pdf

1742-kolnp-2005-granted-form 1.pdf

1742-kolnp-2005-granted-form 18.pdf

1742-kolnp-2005-granted-form 3.pdf

1742-kolnp-2005-granted-form 5.pdf

1742-kolnp-2005-granted-gpa.pdf

1742-kolnp-2005-granted-reply to examination report.pdf

1742-kolnp-2005-granted-specification.pdf

1742-KOLNP-2005-PA.pdf

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Patent Number

226742

Indian Patent Application Number

1742/KOLNP/2005

PG Journal Number

52/2008

Publication Date

26-Dec-2008

Grant Date

24-Dec-2008

Date of Filing

01-Sep-2005

Name of Patentee

NESTE OIL OYJ

Applicant Address

KEILARANTA 8, FI-02150 ESPOO

Inventors:

#	Inventor's Name	Inventor's Address
1	TIITTA, MARJA	VIIKINTIE 11 C 102, FI-06150 PORVOO
2	HARLIN, ELINA	KARPPARINNE 1, FI-01450 VANTAA
3	MAKKONEN, JAANA	SODERKULLANTORI 3 B 12, FI-01150 SODERKULLA
4	KUMAR, NARENDRA	OSTJAKINKATU 5F 28, FI-20750 TURKU
5	MURZIN, DMITRY, YU	VALKIAPAAKATU 2 D, 27, FI-20610 TURKU
6	SALMI, TAPIO	RAKUUNATIE 28, FI-20720 TURKU

PCT International Classification Number

B01J 29/70

PCT International Application Number

PCT/FI2004/000127

PCT International Filing date

2004-03-09

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	20030383	2003-03-14	Finland