A method of controlling particle additions to a fluidized bed reactor includes measuring pressure fluctuations inside the fluidized bed reactor over a selected time period, determining a pressure parameter indicative of amplitudes of the pressure fluctuations, comparing the pressure parameter to a specified threshold, and controlling particle additions to the fluidized bed reactor when the pressure parameter deviates from the specified threshold.

A method for minimizing the amount of catalyst inactivating agent that is present in a liquid fraction recovered from a slurry-based polymer production process, the liquid fraction comprising diluent used in the polymer production process, is disclosed. The method includes steps for controlling the pressure over the liquid fraction collected during diluent recovery so as to minimize the concentration of catalyst inactivating agent that is retained in the recovered liquid fraction. Embodiments of apparatus suitable for conducting the disclosed method are also provided.

A chemical plant or a petrochemical plant or a refinery may include one or more pieces of equipment that process one or more input chemicals to create one or more products. For example, catalytic dehydrogenation can be used to convert paraffins to the corresponding olefin. A delta temperature controller may determine and control differential temperature across the reactor, and use a delta temperature to control a set point for a heater temperature controller. By doing so, the plant may ramp up a catalytic dehydrogenation unit faster and ensure it does not coke up the catalyst and/or foul a screens too quickly. Catalyst activity may be taken into account and allow the plant to have better control over production and run length of the unit.

A method of controlling particle additions to a fluidized bed reactor includes measuring pressure fluctuations inside the fluidized bed reactor over a selected time period, determining a pressure parameter indicative of amplitudes of the pressure fluctuations, comparing the pressure parameter to a specified threshold, and controlling particle additions to the fluidized bed reactor when the pressure parameter deviates from the specified threshold.

A chemical plant or a petrochemical plant or a refinery may include one or more pieces of equipment that process one or more input chemicals to create one or more products. For example, catalytic dehydrogenation can be used to convert paraffins to the corresponding olefin. A delta temperature controller may determine and control differential temperature across the reactor, and use a delta temperature to control a set point for a heater temperature controller. By doing so, the plant may ramp up a catalytic dehydrogenation unit faster and ensure it does not coke up the catalyst and/or foul a screens too quickly. Catalyst activity may be taken into account and allow the plant to have better control over production and run length of the unit.

A withdrawal system for withdrawing particulate matter from a high-temperature unit of a high-temperature industrial process is disclosed. The withdrawal system comprises a material storage silo that comprises a vent line containing a first vent valve, one or more temperature sensors to measure temperature of the particulate matter in the material transfer line, and a controller that receives output measurements from the one or more temperature sensors to monitor and control flow of the particulate matter. The system does not contain a receiving vessel located in the material transfer line between the high-temperature unit and the material storage silo.

A method can include: mixing two or more feedstocks to produce a distillate product; optionally adding a cetane improver to the distillate product; collecting the distillate product in a tank; extracting a distillate product sample from the distillate product after mixing and before collecting in the tank; measuring a derived cetane number and/or a indicated cetane number (DCN/ICN) for the distillate product sample with an online DCN/ICN analyzer; communicating the DCN/ICN to a plant distributed control system; calculating an integrated DCN/ICN for the cumulative distillate product in the tank based on the measured DCN/ICN, previously measured DCN/ICN for portions of the distillate product in the tank, and process variables related to the mixing and cetane improver; and adjusting one or more of the process variables based on the integrated DCN/ICN.

A method of simultaneously modifying degradation rates of at least two compounds including a first compound having a first unmodified degradation rate constant k.sub.1 and a second compound having a second unmodified degradation rate k.sub.2 is provided. The method includes combining a first composition including the first compound with a second composition including the second compound, degrading the first compound and forming a first degradation product; and degrading the second compound and forming a second degradation product. The second degradation product modifies the first unmodified degradation rate constant k.sub.1 of the first compound to a first modified degradation rate k.sub.1 and the first degradation product modifies the second unmodified degradation rate k.sub.2 of the second compound to a second modified degradation rate k.sub.2. Compositions resulting from the method are also provided.

A system and method combine a first reactant with a second reactant to create a reaction product. A first pump is in fluid communication with a reaction vessel and a source of the first reactant. A second pump is in fluid communication with the reaction vessel and a source of the second reactant. A gas sparger is located in the reaction vessel, and the gas sparger is in fluid communication with a gas source for providing gas to the reaction vessel. A controller is configured to execute a program stored in the controller to: (i) receive a sensor signal based on a force exerted by the reaction vessel in a direction toward the sensor, and (ii) operate the first pump and the second pump to deliver to the reaction vessel the first reactant and the second reactant thereby causing a reaction that creates the reaction product.

The invention relates to a neutralization plant (100) comprising at least one reaction chamber (102) having a first feed (114) for an acid-containing product and at least one further feed (116) for a base-containing product, wherein at least one of the feeds (114, 116) comprises at least one valve means (118, 120) for controlling the inflow amount into the reaction chamber (102), wherein the ion controller apparatus (104, 204, 205) comprises at least one evaluation device (106, 206) set up for determining at least one actual ion concentration based on an actual pH of the mixture (122) present in the reaction chamber (102) and wherein the ion controller apparatus (104, 204) comprises at least one ion controller device (108, 208) comprising at least one ion controller (110, 210.1, 210.2, 211) set up for controlling the valve means (118, 120) according to the actual ion concentration and a target ion concentration.