TH32430B - Process for polymerizing monomer in a fluidized base. - Google Patents

Abstract

The invention approaches the polymerization or copolymerization of alpha-olefins, if not alone, in combination with one or more other alpha-olefins. while there is a metallocene catalyst in the gas phase reactor. with fluidized base and the fluidizing medium, which allows the fluidized medium to enter the reactor. It consists of gas and liquid phases.

Claims (9)

1.Processes for the polymerization of alpha-olefins with catalyst. The glass-supported methylosine in the reactor, the gas cycle with the fluidized base, and the fluidized medium in which the fluidizing medium regulates the refrigeration capacity. Cooling of the reactor Said that The process consists of the use of fluidizing media. The level of the liquid entering Reactors, which are more than 2 to 50 percent by weight Using weight Overall Fluidized as base Which maintains the bulk density function (Z) at a value equal to or greater than the limit at Calculate the bulk density function. 2. Process according to claim 1, where the fluid level is approximately 15 percent greater by weight. By using the total weight of the fluidized medium as the base 3. Process according to claim 1, in which the level of the liquid is approximately 20 percent greater than the liquid weight. By using the total weight of the fluidized medium as the base 4. Process according to claim 1, where the level of the fluid in the fluidized medium is based on the overall weight of the fluidized medium. It ranges between about 25 and about 40 percent by weight. 5. Process according to claim 1, which removes the polymer product at a speed greater than approximately 500 lb / h - ft 2. 6. Process according to claim 1, in which the calculated limits range from approximately 0.2 to approximately 0.7. 7. Process according to claim 1 where the calculated limits range from approximately 0.3 to approximately 0.6. 8. Process according to claim 1, where the calculated limits range from approximately 0.4 to approximately 0.6. 9. Process according to claim 1, where the bulk density function (Z) is greater than the limit at Calculate the bulk density function that 1. 0. Process according to claim 1 in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 1 1. The process according to claim 1 where the The foregoing consists of i) butene-1 and ethylene at a mole ratio from approximately 0.001 to approximately 0.60 or 4-methyl-pentene-1. And ethylene at mole ratio from approximately 0.001 to approximately 0.50, or hexene-1 and ethylene at mole ratio from approximately 0.001 to approximately 0.30, or octene-1 and ethylene. that Mole ratios from approx. 0.001 to approx. 0.10; ii) the condensed fluid that has been made up of approximately 1.5 to approx. 20% by mole of the medium. The fluidization is 1 2. Process according to claim 1, in which the aforementioned fluidized intermediates include i) butene-1 and ethylene at a molar ratio from approximately 0.001 to approximately 0.60 or 4-. Methyl-pentene-1 And ethylene at mole ratio from approximately 0.001 to approximately 0.50, or hexene-1 and ethylene at mole ratio from approximately 0.001 to approximately 0.30, or octene-1 and ethylene. that Mole ratios from approx. 0.001 to approx. 0.10; ii) the condensed fluid that has been composed of approximately 1.5 to approx. 30% by mole of the medium. The fluidization is 1 3. The process according to claim 1, in which the aforementioned fluidized intermediate consists of i) butene-1 and ethylene at the mole ratio from Approx. 0.001 to approx. 0.60 or 4-methyl-pentene-1 And ethylene at mole ratio from approximately 0.001 to approximately 0.50, or hexene-1 and ethylene at mole ratio from approximately 0.001 to approximately 0.30, or octene-1 and ethylene. that Mole ratios from approx. 0.001 to approx. 0.10; ii) the condensed fluid that has been composed of approximately 5 to approx 40% by mole of the medium. The fluidizing process was 1. 4. Processes for polymerization of alpha-olefins while having a catalyst. Supported methylocene In gas phase reactors With an anodized base And fluidizing intermediates to produce polymer products with densities in the range of 0.90 g / cm3 to approx. 0.939 g / cm3, the above processes include: The said reaction machine This causes a change in the enthalp of the fluidized medium. Which enters and exits the reactor approximately 35Btu / lb., the fluidized cloud Plus, the level of the liquid entering the reactor is 2 to 50% more by weight. By using the total weight of the fluidizing medium as the base And maintains the bulk density function (Z) at a value equal to or greater than the calculated limit of that bulk density function 1. 5. The process according to claim 14, in which the fluidized medium consists of gas and liquid phase, the level of the liquid entering the reactor. More than approximately 15 percent by weight by weight. The sum of the fluidized medium is base 41. 6. Process according to Clause 14, the enthalpy change It ranges between more than 40 Btu / lb and about 100 Btu / lb1. 7. Procedure according to claim 14, which pulls the product out at a speed greater than approximately 500 lb / h - ft 2 1. 8. Process according to Clause 14 in which the calculated limits range from approximately 0.2 to approximately 0.7 1. 9. Clause 14 Clause 14 where the calculated limit ranges from approximately 0.3 to approximately 0.6 2 0. Clause 14 process in which the Bulk Density (Z) function is greater than the limit at Calculation of the bulk density function 2 1. Method according to claim 14 in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 2. 2.Process for polymerization Alpha-olefin While there is already a supported metallocene catalyst. In gas phase reactors With a fluidized base And intermediaries Fluidized with gas and liquid phases into the reactor The aforementioned processes include; a) control of the cooling capacity of the aforementioned fluidized medium by controlling the ratio of the aforementioned gas cycle Against the said liquid cycle Which intermediary The fluidization consists of a liquid level greater than 2 to 50 percent by weight using the total weight of the fluidized medium as the base; And b) the retention of the bulk density function (Z) at values greater than or equal to the calculated limit. Of the Bulk Density Function 2 3. Process according to claim 22 in which the bulk density function (Z) is greater than the value The calculated limit value of the bulk density function 2 4. Procedures according to claim 22, where the calculated limits range from approximately 0.2 to approximately 0.7 2. 5. Process according to Clause 22 in which the calculated limits range from approximately 0.3 to approximately 0.6 2. 6. Process according to claim 22 in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 2. 7. Procedure according to claim 22, in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 2. 8. Process according to claim 22, in which the liquid phase consists of the level of About 15 percent more liquid by weight By using the total weight of the middle Fluidized to base 2 9. Process according to claim 22, in which the liquid phase consists of the level of About 20 percent more liquid by weight By using the total weight of the middle Fluidized to base 3 0. Process according to claim 22, in which the liquid phase consists of the level of About 25 percent more liquid by weight By using the total weight of the middle Fluidizing as a base 3. 1. Processes for polymerization. Alpha-olefin While there is already a supported metallocene catalyst. In gas phase reactors With a fluidized base And fluidizing intermediates for the production of polymer products with densities ranging from approx. More than 0.900 g / m3 to 0.970 g / cm3, the above processes include By operating the reactor already mentioned This causes the change in the enthalpy of the fluidized medium entering and leaving the reactor more than approximately 35 Btu / lb, the fluidized medium. Include level Reserve the reaction device that is 2 to 50 percent greater by weight by weight. Overall of the fluidized medium is the base. And which maintains the balk thickness function (Z) at a value equal to or greater than the calculated limit of the bulk density function. The gas-liquid phase is included in which the level of the liquid added to the reactor is approximately 20% greater by weight using the overall weight of the fluidized medium as base 3. 3. Clause 31 claim process, where enthalpy changes range between approximately 40 Btu / lb, to approximately 110 Btu / lb, 3. 4. Clause 31 process that pulls products out at a greater speed. Approximately 500 pounds / hour - 2 feet 3 5. Process according to claim 31, in which the bulk density layer (Z) function is greater than the limit at Calculate the bulk density function that 3. 6. Process according to Clause 31, where the calculated limits range from approximately 0.2 to approximately 0.7 3. 4. Process according to Clause 31 where the calculated limits range from approximately 0.3 to approximately 0.6 3. 8. Procedure according to Clause 31 in which the calculated limits range from approximately 0.4 to approximately 0.6 3. 9. Procedure according to claim 35, in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 4. 0. Process for polymerization Alpha-olefin While there is already a supported metallocene catalyst. In gas phase reactors With a fluidized base And the fluidizing medium That entered the reaction machine The fluidized medium has a gas phase and a liquid phase. That way Included; a) control of the cooling capacity of the aforementioned fluidized medium by controlling the ratio of the aforementioned gas cycle Against the said liquid cycle Which intermediary The fluidization consists of a level of more than 2 to 50 percent of the liquid by weight using the total weight of the fluidized medium as the base; b) Calculation of the bulk density tooth function; c) Monitoring the bulk density function (Z) and d). Variation of the bulk density function (Z) maintains the bulk density function (Z) at a value greater than or equal to the calculated limit of the bulk density function (Z). Bulk density 4 1. Method according to claim 40, which maintains the bulk density function (Z) at greater value. The calculated limit value of the bulk density function 4 2. The method according to claim 40, where the calculated limit ranges from approximately 0.2 to approximately 0.7 4. 3. The process according to Clause 40 in which the calculated limits range from approximately 0.3 to approximately 0.6 4. 4. Procedures according to claim 40 in which the gas phase values enter the reactor separately and separately from the liquid phase 4. 5. Process according to claim 40, where the gas phase value enters the reactor above or below the distributor plate 4. 6. Process according to claim 40 in which the bulk density function (Z) is greater than 1% of the calculated limit of the bulk density function 4. 7. Process according to claim 40, which liquid phase Including the level of liquids greater than 20 percent by weight Using weight By the sum of the fluidizing medium is base 4. 8. Process according to claim 40, which regulates cooling capacity. By adding fluid That condenses, such as a reaction machine Or a stream of recycling 4 9. Process according to claim 40, which maintains the bulk density function (Z) at greater value. The calculated limit of the bulge probability function is 5. 0. Clause 40 process, where the calculated limits range from approximately 0.2 to approximately 0.7 5 1. The process of claim 40, where the liquid phase consists of the degree of More than 20 percent liquid by weight By using the total weight of the fluidized medium as the base