MX2007002283A - Optimized liquid-phase oxidation. - Google Patents

Abstract

Disclosed is an optimized process and apparatus for more efficiently and economically carryingout the liquid-phase oxidation of an oxidizable compound. Such liquid-phase oxidationis carried out in a bubble column reactor that provides for a highly efficientreaction at relatively low temperatures. When the oxidized compound is para-xyleneand the product from the oxidation reaction is crude terephthalic acid (CTA),such CTA product can be purified and separated by more economical techniquesthan could be employed if the CTA were formed by a conventional high-temperature oxidationprocess.

Description

OPTIMIZED LIQUID PHASE OXIDATION FIELD OF THE INVENTION This invention relates generally to a process for the catalytic oxidation, in liquid phase of an aromatic compound. One aspect of the invention relates to the partial oxidation of a dialkyl aromatic compound (e.g. para-xylene) to produce a crude aromatic dicarboxylic acid (e.g., crude terephthalic acid), which can then be subjected to purification and separation. Another aspect of the invention relates to an improved bubble column reactor that provides a more effective and economical liquid phase oxidation process. BACKGROUND OF THE INVENTION Liquid phase oxidation reactions are employed in a variety of existing commercial processes. For example, liquid phase oxidation is currently used for the oxidation of aldehydes to acids (eg, propionaldehyde to propionic acid), the oxidation of cyclohexane to adipic acid, and the oxidation of alkyl aromatics to alcohols, acids or diacids. A particularly significant commercial oxidation process in the latter category (oxidation of alkyl aromatics) is the partial liquid catalytic oxidation of para-xylene to terephthalic acid. Terephthalic acid is a compound important with a variety of applications. The primary use of terephthalic acid is as a feedstock in the production of polyethylene terephthalate (PET). PET is a well-known plastic used in large quantities around the world to make products such as bottles, fibers and packaging or packaging. In a typical liquid phase oxidation process, which includes the partial oxidation of para-xylene to terephthalic acid, a liquid phase feed stream and a gas phase oxidant stream are introduced into a reactor and form a reaction medium of multiple phases in the reactor. The liquid phase feed stream introduced into the reactor contains at least one oxidizable organic compound (for example, para-xylene), while the gas phase oxidant stream contains molecular oxygen. At least a portion of the molecular oxygen introduced into the reactor as a gas is dissolved in the liquid phase of the reaction medium to provide oxygen availability for the reaction in the liquid phase. If the liquid phase of the multi-phase reaction medium contains an insufficient concentration of molecular oxygen (ie, if certain portions of the reaction medium are "undernourished with oxygen"), undesirable side reactions may generate impurities and / or the proposed reactions they can be retarded in speed. If the phase liquid of the reaction medium contains very little of the oxidizable compound, the reaction rate can be undesirably slow. In addition, if the liquid phase of the reaction medium contains an excess concentration of the oxidizable compound, additional undesirable side reactions can generate impurities. Conventional liquid phase oxidation reactors are equipped with stirring means for mixing the multi-phase reaction medium contained therein. The agitation of the reaction medium is provided in an effort to promote the dissolution of molecular oxygen in the liquid phase of the reaction medium, maintains relatively uniform concentrations of dissolved oxygen in the liquid phase of the reaction medium, and maintains relatively uniform concentrations of the reaction medium. oxidizable organic compound in the liquid phase of the reaction medium. Agitation of the reaction medium that is subjected to liquid phase oxidation is often provided by means of mechanical agitation in containers such as, for example, continuous stirred tank reactors (CSTRs). Although the CSTRs can provide complete mixing of the reaction medium, the CSTRs have a number of disadvantages. For example, CSTRs have a relatively high capital cost due to their requirement for expensive motors, fluid sealed bearings and thrust shafts, and / or complex agitation mechanisms. In addition, the mechanical components of rotation and / or oscillation of conventional CSTRs require regular maintenance. The work and unemployment time associated with such maintenance is added to the operating cost of the CSTRs. However, even with regular maintenance, the mechanical agitation systems employed in the CSTRs are prone to mechanical failure and may require replacement for relatively short periods of time. Bubbling column reactors provide an attractive alternative to CSTRs and other mechanically agitated oxidation reactors. The bubble column reactors provide agitation of the reaction medium without the requirement of expensive and unreliable mechanical equipment. Bubble column reactors typically include an elongated vertical reaction zone within which the reaction medium is contained. Agitation of the reaction medium in the reaction zone is mainly provided by the natural flotation of the gas bubbles that rise through the liquid phase of the reaction medium. This natural flotation agitation provided in bubble column reactors reduces capital and maintenance costs relative to mechanically agitated reactors. In addition, the substantial absence of moving mechanical parts associated with the bubble column reactors provides an oxidation system that is less prone to mechanical failure than mechanically agitated reactors. When the partial liquid phase oxidation of para-xylene is carried out in a conventional oxidation reactor (CSTR or bubble column), the product withdrawn from the reactor is typically a suspension comprising crude terephthalic acid (CTA) and a mother liquor. . The CTA contains relatively high levels of impurities (eg, 4-carboxybenzaldehyde, para-toluic acid, fluorenones, and other colored bodies) rendering it unsuitable as a feedstock for PET production. Thus, the CTA produced in conventional oxidation reactors typically undergoes a purification process that converts the CTA into purified terephthalic acid. (PTA) suitable to make PET. A typical purification process to convert the CTA to PTA includes the following steps: (1) replace the mother liquor of the suspension containing CTA with water, (2) heat the CTA / water suspension to dissolve the CTA in water, ( 3) catalytically hydrogenate the CTA / water solution to convert the impurities to more desirable and / or easily separable compounds, (4) precipitate the resulting PTA from the hydrogenated solution via the multiple crystallization steps, and (5) separate the PTA crystallized from the remaining liquids. Although effective, this type of process Conventional purification can be very expensive. Individual factors that contribute to the high cost of conventional CTA purification methods include, for example, the thermal energy required to promote the dissolution of CTA in water, the catalyst required for hydrogenation, the hydrogen current required for hydrogenation, the loss of performance caused by the hydrogenation of some terephthalic acid and the multiple vessels required for multi-stage crystallization. Thus, it would be desirable to provide a CTA product that could be purified without requiring heat-promoted dissolution in water, hydrogenation and / or multistage crystallization. OBJECTIVES OF THE INVENTION It is, therefore, an object of the present invention to provide a more effective and economical liquid phase oxidation reactor and process. Another object of the invention is to provide a more effective and economical reactor and process for the catalytic partial oxidation in liquid phase of para-xylene to terephthalic acid. Still another object of the invention is to provide a bubble column reactor that facilitates improved liquid phase oxidation reactions with reduced formation of impurities. Still another object of the invention is provide a more effective and economical system to produce pure terephthalic acid (PTA) via the liquid phase oxidation of para-xylene to produce crude terephthalic acid (CTA) and subsequently purify CTA to PTA. A further object of the invention is to provide a bubble column reactor to oxidize the para-xylene and produce a CTA product capable of being purified without requiring the heat-promoted dissolution of the CTA in water, the hydrogenation of the dissolved CTA and / or the crystallization of multiple stages of the hydrogenated PTA. It should be noted that the scope of the present invention, as defined in the appended claims, is not limited to processes or apparatus capable of accomplishing all of the objectives listed in the foregoing. Rather, the scope of the claimed invention may encompass a variety of systems that do not all or any of the objectives listed in the foregoing. Further objects and advantages of the present invention will be readily apparent to one skilled in the art upon review of the following detailed description and associated drawings. BRIEF DESCRIPTION OF THE INVENTION One embodiment of the present invention relates to a process comprising the following steps: (a) introducing a feed stream comprising a oxidizable compound in a reaction zone of a bubble column reactor; (b) introducing a first oxidant stream comprising molecular oxygen in the reaction zone via one or more lower oxidant orifices; e (c) introducing a second oxidant stream comprising molecular oxygen in the reaction zone via one or more higher oxidant orifices, wherein the reaction zone has a maximum diameter (D), wherein the orifices of Higher oxidants are located in at least about ID above the lower oxidant orifices, wherein the first and second oxidant stream each contains less than 50 mole percent molecular oxygen. Another embodiment of the present invention relates to a process for producing terephthalic acid comprising the following steps: (a) introducing a predominantly liquid phase feed stream comprising para-xylene in a reaction zone of a bubble column reactor; (b) introducing a first oxidant stream predominantly in the gas phase in the reaction zone via one or more lower oxidant orifices; (c) introducing a second oxidant stream predominantly in the gas phase in the reaction zone via one or more higher oxidant orifices, wherein the reaction zone has a maximum diameter (D), in wherein the upper and lower oxidant orifices are vertically spaced from one another by at least about ID; (d) oxidizing at least a portion of para-xylene in a liquid phase of a multi-phase reaction medium contained in the reaction zone to thereby form crude terephthalic acid; and (e) oxidizing at least a portion of the crude terephthalic acid in a secondary oxidation reactor to thereby form purest terephthalic acid. Yet another embodiment of the present invention relates to a bubble column reactor for reacting a predominantly liquid phase stream and a predominantly gas phase stream. The bubble column reactor includes a container shell, one or more liquid orifices, and a plurality of gas orifices. The vessel shell defines a reaction zone. The reaction zone has a normally lower end and a normally superior end spaced from one another by a maximum axial distance (L). The reaction zone has a maximum diameter (D) and a L: D ratio of at least about 3: 1. The one or more liquid orifices introduce the stream in liquid phase in the reaction zone. The plurality of gas orifices introduce the gas phase current in the reaction zone. At least two of the gas orifices are axially spaced from one to the other by at least approximately ID. At least one of the gas orifices is located within approximately 0.25 L of the normally lower end. BRIEF DESCRIPTION OF THE DRAWINGS Preferred embodiments of the invention are described in detail below with reference to the figures of accompanying drawings, wherein; FIG. 1 is a side view of an oxidation reactor constructed in accordance with an embodiment of the present invention, which particularly illustrates the introduction of feed, oxidant and reflux streams in the reactor, the presence of a multi-phase reaction medium in the reactor, and removal of a gas and a suspension of the top and bottom of the reactor, respectively; FIG. 2 is an enlarged sectional side view of the bottom of the bubble column reactor taken along line 2-2 in FIG. 3, which particularly illustrates the location and configuration of an oxidant spray tube used to introduce the oxidant stream into the reactor; FIG. 3 is a top view of the oxidant spray tube of FIG. 2, which particularly illustrates the oxidant orifices in the upper part of the oxidant spraying tube; FIG. A is a bottom view of the oxidant sprayer tube of FIG. 2, which particularly illustrates the oxidant orifices at the bottom of the oxidant spray tube; FIG. 5 is a sectional side view of the oxidant spray tube taken along line 5-5 in FIG. 3, which particularly illustrates the orientation of the oxidant holes in the top and bottom of the oxidant spray tube; FIG. 6 is an enlarged side view of the bottom portion of the bubble column reactor, particularly illustrating a system for introducing the feed stream into the reactor at vertically spaced, multiple locations; FIG. 7 is a sectional top view taken along line 7-7 in FIG. 6, which particularly illustrates how the feed introduction system shown in FIG. ß distributes the feed stream in a preferred radial feed zone (FZ) and more than one azimuth quadrant (Qi, Q2, Q3, Q4); FIG. 8 is a sectional top view similar to FIG. 7, but illustrating an alternative means for discharging the feed stream into the reactor using bayonet tubes each having a plurality of small feed holes; FIG. 9 is an isometric view of an alternative system for introducing the feed stream into the reaction zone in multiple vertically spaced locations without requiring multiple container penetrations, which particularly illustrates that the feed distribution system can be at least partially supported on the oxidant spray tube; FIG. 10 is a side view of the single penetration feed distribution system and the oxidant spray tube illustrated in FIG. 9; FIG. 11 is a sectional top view taken along line 11-11 in FIG. 10 and further illustrating the single penetration feed distribution system supported on the oxidant spray tube; FIG: 12 is an isometric view of an alternative oxidant spray tube having all of the oxidant orifices located at the bottom of the ring member; FIG. 13 is a top view of the alternative oxidant spray tube of FIG. 12; FIG. 14 is a bottom view of the alternative oxidant spray tube of FIG. 12, which particularly illustrates the location of the bottom holes to introduce the oxidant stream into the reaction zone; FIG. 15 is a sectional side view of the oxidant spray tube taken along line 15-15 in FIG. 13, which particularly illustrates the orientation of the lower oxidant holes; FIG. 16 is a side view of a bubble column reactor equipped with an internal deaeration vessel near the bottom outlet of the reactor; FIG. 17 is an enlarged sectional side view of the lower portion of the bubble column reactor of FIG. 16 taken along line 17-17 in FIG. 18, which particularly illustrates the configuration of the internal deaeration vessel placed in the bottom outlet of the bubble column reactor. FIG. 18 is a sectional top view taken along line 18-18 in FIG. 16, which particularly illustrates a vortex breaker placed in the deaeration vessel; FIG. 19 is a side view of a bubble column reactor equipped with an external deaeration vessel and illustrating the manner in which a portion of the deaerated suspension exiting the bottom of the deaeration vessel can be used to flood a line of desalination. -inventariation coupled to the bottom of the reactor; FIG. 20 is a side view of a bubble column reactor equipped with a container of hybrid internal / external deaeration to decouple the gas phase from a reaction medium withdrawn from a high side location in the reactor; FIG. 21 is a side view of a bubble column reactor equipped with an alternative hybrid deaeration vessel near the bottom of the reactor; FIG. 22 is an enlarged sectional side view of the lower portion of the bubble column reactor of FIG. 21, which particularly illustrates the use of an alternative oxidant spray tube that employs inlet conduits that receive the oxidant stream through the bottom end of the reactor; FIG. 23 is an enlarged sectional side view similar to FIG. 22, which particularly illustrates an alternative means for introducing the oxidant stream into the reactor via a plurality of holes in the lower head of the reactor and, optionally, employing shock plates to more evenly distribute the oxidant stream in the reactor. reactor; FIG. 24 is a side view of a bubble column reactor employing an internal flow conduit to help improve the dispersion of an oxidizable compound by recirculating a portion of the reaction medium from an upper portion of the reactor to a lower portion of the reactor; FIG. 25 is a side view of a bubble column reactor employing an external flow conduit to help improve the dispersion of the oxidizable compound by recirculating a portion of the reaction medium from an upper portion of the reactor to a lower portion of the reactor; FIG. 26 is a sectional side view of a horizontal eductor that can be used to improve the dispersion of the oxidizable compound in an oxidation reactor, particularly illustrating an eductor that uses incoming liquid feed to remove the reaction medium in the eductor and discharges the feed mixture and the reaction medium in a high-speed reaction zone; FIG. 27 is a sectional side view of a vertical eductor that can be used to improve the dispersion of the oxidizable compound in an oxidation reactor, which particularly illustrates an eductor that combines the liquid feed and the inlet gas and uses the combined two-phase fluid for removing the reaction medium in the eductor and discharging the liquid feed mixture, inlet gas, and the reaction medium in a high speed reaction zone; FIG. 28 is a side view of a bubble column reactor containing a reaction medium of multiple phases, which particularly illustrates the reaction medium which is theoretically divided into 30 horizontal cuts of equal volume in order to quantify certain ingredients in the reaction medium; FIG. 29 is a side view of a bubble column reactor containing a multi-phase reaction medium, particularly illustrating the first and second discrete 20 percent continuous volume of the reaction medium having oxygen concentrations and / or proportions of substantially different oxygen consumption; FIG. 30 is a side view of two stacked reaction vessels, with or without optional mechanical agitation, containing a multi-phase reaction medium particularly illustrating that the containers contain discrete 20 percent continuous volumes of the reaction medium having concentrations of oxygen and / or proportions of oxygen consumption substantially different; FIG. 31 is a side view of three side-by-side reaction vessels, with or without optional mechanical agitation, containing a multi-phase reaction medium, which particularly illustrates that the containers contain discrete 20 percent continuous volumes of the reaction medium that have oxygen concentrations and / or substantially different oxygen consumption ratios; FIG. 32 is a side view of a stage speed bubbling column reactor having a broad lower reaction zone and a reduced upper reaction zone; FIG. 33 is a side view of a bubble column reactor equipped with a vertical divider wall for adding a vertical surface area contacting the reaction medium; FIG. 34 is a sectional view taken along line 34-34 in FIG. 33, which particularly illustrates that the dividing wall is a planar member that divides the reaction zone into two substantially equal sections; FIG. 35 is a side view of a bubble column reactor equipped with a vertical dividing wall shortened to add vertical surface area making contact with the reaction medium; FIG. 36 is a side view of a bubble column reactor equipped with a vertical divider wall shortened and curved to add vertical surface area contacting the reaction medium; FIG. 37 is a sectional view taken along line 37-37 in FIG. 36, which particularly illustrates that the curved vertical dividing wall is a member generally in the form of S that divides a portion in the reaction zone into two substantially equal sections; FIG. 38 is a side view of a bubble column reactor equipped with a shortened vertical internal member for adding vertical surface area contacting the reaction medium; FIG. 39 is a sectional view taken along line 39-39 in FIG. 38, which particularly illustrates that the vertical inner member has an "X" shape and the edges of the inner member do not extend completely to the side wall of the reactor; FIG. 40 is a side view of a bubble column reactor equipped with differently configured, alternate vertical internal members for the addition of vertical surface area contacting the reaction medium; FIG. 41 is a sectional view taken along line 41-41 in FIG. 40, which particularly illustrates a configuration of the vertical members that have an "X" shape and divides a portion in the reaction zone into four substantially equal quadrants; FIG. 42 is a sectional view taken along line 42-42 in FIG. 40, which particularly illustrates the other configuration of the vertical members that divides a portion of the reaction zone into eight sections in shape wedge substantially equal; FIG. 43 is a side view of a bubble column reactor equipped with a plurality of helical internal members for adding vertical surface area contacting the reaction medium; FIG. 44 is a sectional view taken along line 44-44 in FIG. 43, which particularly illustrates the shape of one of the internal members in helical form; FIG. 45 is a side view of a bubble column reactor equipped with a plurality of diverters, each comprising a plurality of cylindrical rods to contact the reaction medium; FIG. 46 is an enlarged isometric view of the derailleurs of FIG. 45, which particularly illustrates the manner in which the cylindrical rods of adjacent deviators are rotated 90 degrees relative to each other; FIG. 47 is a sectional view taken along line 47-47 in FIG. 45, which particularly illustrates only one of the deviators; FIG. 48 is a side view of a bubble column reactor equipped with a plurality of diverters, each comprising a plurality of members of section L to make contact with the reaction medium; FIG. 49 is an enlarged side view of the diverters of FIG. 48, which particularly illustrates the manner in which the L-section members of the adjacent deviators are rotated 90 degrees relative to each other; FIG. 50 is a sectional view taken along line 50-50 in FIG. 48, which particularly illustrates only one of the deviators, FIG. 51 is a side of a bubble column reactor equipped with a single diamond-shaped, cylindrical, monolithic diverter for contacting the reaction medium; FIG. 52 is an enlarged side view of the monolithic diverter of FIG. 51; FIG. 53 is a sectional view taken along line 53-53 in FIG. 51 and illustrating the cylindrical nature of the monolithic diverter; FIG. 54 is a side view of a bubble column reactor having multiple vertically spaced inlets for introducing the oxidant stream into the reaction zone; FIGS. 55A and 55B are enlarged views of crude terephthalic acid (CTA) particles produced according to one embodiment of the present invention, which particularly illustrate that each CTA particle is a high density, low surface area particle composed of a plurality of CTA sub-particles loosely linked; FIGS. 56A and 56B are enlarged views of a conventionally produced CTA, which particularly illustrates that the conventional CTA particle has a larger particle size, low density, and lower surface area than the inventive CTA particle of FIGS. 55A and 55B; FIG. 57 is a simplified process flow diagram of a prior art process for making purified terephthalic acid (PTA); FIG. 58 is a simplified process flow diagram of a process for making PTA according to an embodiment of the present invention; and FIG. 59 is a table summarizing various operating parameters of a bubble column oxidation reactor, wherein certain operating parameters have been adjusted according to the description provided in the Examples section. DETAILED DESCRIPTION One embodiment of the present invention relates to the partial oxidation in liquid phase of an oxidizable compound. Such oxidation is preferably carried out in the liquid phase of a multi-phase reaction medium contained in one or more stirred reactors. Suitable stirred reactors include, for example, stirred reactors of bubbling (e.g., bubble column reactors), mechanically agitated reactors (e.g., continuous stirred tank reactors), and stirred flow reactors (e.g., jet reactors). In one embodiment of the invention, the liquid phase oxidation is carried out in a single bubble column reactor. As used herein, the term "bubble column reactor" will denote a reactor for facilitating chemical reactions in a multi-phase reaction medium, wherein the agitation of the reaction medium is provided primarily by the upward movement of the reaction medium. the gas bubbles through the reaction medium. As used herein, the term "agitation" will denote the work dissipated in the reaction medium that causes fluid flow and / or mixing. As used herein, the terms "majority," "primarily," and "predominantly" will denote more than 50 percent. As used herein, the term "mechanical agitation" will denote the agitation of the reaction medium caused by the physical movement of a rigid (s) or flexible element (s) against or within the reaction medium. . For example, mechanical agitation may be provided by rotation, oscillation, and / or vibration of internal agitators, paddles, vibrators, or acoustic diaphragms located in the reaction medium. As used herein, the term "flow agitation" will denote the agitation of the reaction medium caused by the injection and / or high-speed recirculation of one or more fluids in the reaction medium. For example, flow agitation may be provided by nozzles, ejectors and / or eductors. In a preferred embodiment of the present invention, less than about 40 percent of the agitation of the reaction medium in the bubble column reactor during oxidation is provided by mechanical and / or flow agitation, more preferably less than about 20. percent of the agitation is provided by the mechanical agitation and / or flow, and much more preferably less than 5 percent of the agitation is provided by the mechanical and / or flow agitation. Preferably, the amount of mechanical and / or flow agitation imparted to the multi-phase reaction medium during oxidation is less than about 3 kilowatts per cubic meter of the reaction medium, more preferably less than 2 kilowatts per cubic meter, and much more preferably less than 1 kilowatt per cubic meter. With reference now to FIG. 1, a preferred bubble column reactor 20 is illustrated as comprising a container shell 22 having a reaction section 24 and a decoupling section 26. The reaction section 24 defines an internal reaction zone 28, while the coupling section 26 defines an internal decoupling zone 30. A predominantly liquid-phase feed stream is introduced into the reaction zone 28 via the feed inlets 32a, b, c, d. An oxidant stream predominantly in gas phase is introduced into the reaction zone 28 via an oxidant spray tube 34 located in the lower portion of the reaction zone 28. The liquid phase feed stream and the The gas phase oxidant cooperatively forms a multi-phase reaction medium 36 within the reaction zone 28. The multi-phase reaction medium 36 comprises a liquid phase and a gas phase. More preferably, the multi-phase reaction medium 36 comprises a three phase medium having solid phase, liquid phase and gas phase components. The solid phase component of the reaction medium 36 preferably precipitates within the reaction zone 28 as a result of the oxidation reaction carried out in the liquid phase of the reaction medium 36. The bubbling column reactor 20 includes an output of suspension 38 located near the bottom of the reaction zone 28 and a gas outlet 40 located near the top of the decoupling zone 30. A suspension effluent comprising liquid phase and solid phase components of a reaction 36 is removed from reaction zone 28 via suspension outlet 38, while a predominantly gaseous effluent is removed from the coupling zone 30 via the gas outlet 40. The in-phase feed stream liquid introduced into the bubble column reactor 20 via the feed inlets 32a, b, c, d preferably comprises an oxidizable compound, a solvent and a catalyst system. The present oxidizable compound in the liquid phase feed stream preferably comprises at least one hydrocarbyl group. More preferably, the oxidizable compound is an aromatic compound. Still more preferably, the oxidizable compound is an aromatic compound with at least one linked hydrocarbyl group or at least one linked substituted hydrocarbyl group or at least one linked heteroatom or at least one linked carboxylic acid (-COOH) function. Even more preferably, the oxidizable compound is an aromatic compound with at least one linked hydrocarbyl group or at least one substituted hydrocarbyl group bonded to each linked group comprising from 1 to 5 carbon atoms. Still more preferably, the oxidizable compound is an aromatic compound having exactly two groups bonded to each linked group which comprises exactly one carbon atom and which consists of methyl groups and / or substituted methyl groups and / or at most one carboxylic acid group. Still more preferably, the oxidizable compound is para-xylene, meta-xylene, para-tolualdehyde, meta-tolualdehyde, para-toluic acid, meta-toluic acid, and / or acetaldehyde. Most preferably, the oxidizable compound is para-xylene. A "hydrocarbyl group," as defined herein, is at least one carbon atom that is bonded only to hydrogen atoms or other carbon atoms.A "substituted hydrocarbyl group", as defined herein, is at least one carbon atom attached to at least one hetero atom and to at least one hydrogen atom. "Heteroatoms", as defined herein, are all atoms other than carbon and hydrogen atoms. as defined herein, they comprise an aromatic ring, preferably having at least 6 carbon atoms, even more preferably having only carbon atoms as part of the ring Suitable examples of such aromatic rings include, but are not limited to, , benzene, biphenyl, terphenyl, naphthalene, and other carbon-based fused aromatic rings Suitable examples of the oxidizable compound include aliphatic hydrocarbons (eg, alkanes, branched grains, cyclic alkanes, aliphatic alkenes, branched alkenes and cyclic alkenes); aliphatic aldehydes (by example, acetaldehyde, propionaldehyde, isobutyraldehyde, and n-butyraldehyde); aliphatic alcohols (e.g., ethanol, isopropanol, n-propanol, n-butanol, and isobutanol); aliphatic ketones (for example, dimethyl ketone, ethyl methyl ketone, diethyl ketone, and isopropyl methyl ketone); aliphatic esters (e.g., methyl formate, methyl acetate, ethyl acetate); aliphatic, peroxide peroxides and hydroperoxides (e.g., t-butyl hydroperoxide, paracetic acid and di-t-butyl hydroperoxide); aliphatic compounds with groups which are combinations of the above aliphatic species plus other heteroatoms (for example, aliphatic compounds comprising one or more molecular segments of hydrocarbons, aldehydes, alcohols, ketones, esters, peroxides, perishes, and / or hydroperoxides in combination with sodium, bromine, cobalt, manganese, and zirconium); various benzene rings, naphthalene rings, biphenyls, terphenyls, and other aromatic groups with one or more linked hydrocarbyl groups (eg, toluene, ethylbenzene, isopropylbenzene, n-propylbenzene, neopentylbenzene, para-xylene, meta-xylene, ortho- xylene, all isomers of trimethylbenzenes, all isomers of tetramethylbenzenes, pentamethylbenzene, hexamethylbenzene, all isomers of ethylmethylbenzenes, all isomers of diethylbenzenes, all isomers of ethyl-dimethylbenzenes, all isomers of dimethylnaphthalenes, all isomers of ethyl- methylnaphthalenes, all isomers of diethylnaphthalenes, all isomers of dimethylbiphenyls, all isomers of ethyl-methylbiphenyls, and all isomers of diethylbiphenyls, stilbenes and with one or more linked hydrocarbyl groups, fluorene and with one or more linked hydrocarbyl groups, anthracene and with one or more linked hydrocarbyl groups, and diphenylethane and with one or more linked hydrocarbyl groups); various benzene rings, naphthalene rings, biphenyls, terphenyls, and other aromatic groups with one or more linked hydrocarbyl groups and / or one or more linked heteroatoms, which may be connected to other atoms or groups of atoms (eg, phenol, all isomers of methylphenols, all isomers of dimethylphenols, all isomers of naphthols, methyl ether of benzyl, all isomers of bromophenols, bromobenzene, all isomers of bromotoluenes including alpha-bromotoluene, dibromobenzene, cobalt naphthenate and all isomers of bromobiphenyls); various benzene rings, naphthalene rings, biphenyls, terphenyls, and other aromatic groups with one or more linked hydrocarbyl groups and / or one or more linked heteroatoms and / or one or more linked substituted hydrocarbyl groups (eg, benzaldehyde, all the isomers of bromobenzaldehydes, all isomers of brominated tolualdehydes including all isomers of alpha-tolualdehydes, all isomers of hydroxybenzaldehydes, all isomers of bromohydroxybenzaldehydes, all isomers of benzene dicarboxaldehydes, all isomers of benzene tricarboxaldehydes, para-tolualdehyde, meta-tolualdehyde, ortho-tolualdehyde, all isomers of toluene dicarboxaldehydes, all isomers of toluene tricarboxaldehydes, all tetracarboxaldehídos isomers toluene, all isomers of dimethylbenzene dicarboxaldehídos, all isomers of dimethylbenzene tricarboxaldehídos, all isomers of dimethylbenzene tetracarboxaldehídos, all isomers of trimethylbenzene tricarboxaldehídos, all isomers of etiltolualdehídos, all isomers dicarboxaldehídos trimethylbenzene, tetramethylbenzene dicarboxaldehyde, hydroxymethyl benzene, all isomers of hydroxymethyl-toluenes, all isomers of hydroxymethyl-bromotoluenes, all isomers of • hydroxymethyl tolualdehydes, all isomers of hydroxymethyl-bromotolualdehyde, benzyl hydroperoxide, benzoyl hydroperoxide, all isomers of tolyl methyl hydroperoxides, and all isomers of methylphenol methyl hydroperoxides); various benzene rings, naphthalene rings, biphenyls, terphenyls, and other aromatic groups with one or more linked selected groups, selected groups signifying linked hydrocarbyl groups and / or heteroatoms and / or substituted hydrocarbyl groups and / or carboxylic acid groups and / or peroxy acid groups (for example, benzoic acid, para-toluic acid, meta-toluic acid, ortho-toluic acid, all isomers of ethylbenzoic acids, all isomers of propylbenzoic acids, all isomers of butylbenzoic acids, all isomers of pentylbenzoic acids, all isomers of dimethylbenzoic acids, all isomers of ethylmethylbenzoic acids, all isomers of trimethylbenzoic acids, all isomers of tetramethylbenzoic acids, pentamethylbenzoic acid, all isomers of diethylbenzoic acids, all isomers of benzene dicarboxylic acids, all isomers of benzene tricarboxylic acids, all isomers of methylbenzene dicarboxylic acids, all isomers of dimethylbenzene dicarboxylic acids, all isomers of methylbenzene tricarboxylic acids, all isomers of bromobenzoic acids, all isomers of dibromobenzoic acids, all isomers of bromotolic acid s which include alpha-bromotolytics, tolyl acetic acid, all isomers of hydroxybenzoic acids, all isomers of hydroxy ethyl-benzoic acids, all isomers of hydroxytoluic acids, all isomers of hydroxymethyl-toluic acids, all isomers of hydroxymethyl acids -benzene dicarboxylic, all isomers of hydroxybromobenzoic acids, all isomers of hydroxybromotoluic acids, all isomers of acids hydroxymethyl-bromobenzoic, all isomers of carboxy benzaldehydes, all isomers of dicarboxy benzaldehydes, perbenzoic acid, all isomers of hidroperoximetil-benzoic acids, all isomers of hidroperoximetil-hydroxybenzoic acids, all isomers of hidroperoxicarbonil-benzoic acids, all isomers hidroperoxicarbonil-toluenes, all isomers of metilbifenilocarboxílicos acids, all isomers of dimethylbiphenyl carboxylic acids, all isomers of methylbiphenyl dicarboxylic acids, all isomers of biphenyl tricarboxylic acids, all isomers of stilbene with one or more attached selected groups, all isomers of fluorenone with one or more attached selected groups, all isomers of acids of naphthalene with one or more attached selected groups, benzyl, all isomers of benzyl with one or more attached selected groups, benzophenone, all isomers be nzofenona with one or more attached selected groups, anthraquinone, all isomers of anthraquinone with one or more attached selected groups, all isomers of diphenylethane with one or more attached selected groups, benzocoumarin, and all isomers of benzocoumarin with one or more groups Selected linked). If the oxidizable compound present in the liquid phase feed stream is a compound normally solid (i.e., is a solid at standard temperature and pressure), it is preferred that the oxidizable compound is substantially dissolved in the solvent when introduced into reaction zone 28. It is preferred for the boiling point of the oxidizable compound at atmospheric pressure that is at least approximately 50 ° C. More preferably, the boiling point of the oxidizable compound is in the range of about 80 to about 400 ° C, and much more preferably in the range of about 125 to 155 ° C. The amount of the oxidizable compound present in the liquid phase feed is preferably in the range of about 2 to about 40 weight percent, more preferably in the range of about 4 to about 20 weight percent, and most preferably in the range range of 6 to 15 weight percent. It is now mentioned that the oxidizable compound present in the liquid phase feed may comprise a combination of two or more different oxidizable chemicals. These two or more different chemical materials can be fed mixed into the liquid phase feed stream or they can be fed separately into multiple feed streams. For example, an oxidizable compound comprising para-xylene, meta-xylene, para-tolualdehyde, para-toluic acid and acetaldehyde can be fed to the reactor via single input or multiple separate inputs. The solvent present in the liquid phase feed stream preferably comprises an acid component and a water component. The solvent is preferably present in the liquid phase feed stream in a concentration in the range of about 60 to about 98 weight percent, more preferably in the range of about 80 to about 96 weight percent, and much more preferably in the range of 85 to 94 weight percent. The acid component of the solvent is preferably primarily an organic low molecular weight monocarboxylic acid having 1-6 carbon atoms, more preferably 2 carbon atoms. Most preferably, the acid component of the solvent is mainly acetic acid. Preferably, the acid component constitutes at least about 75 weight percent of the solvent, most preferably at least about 80 weight percent of the solvent, and most preferably 85 to 98 weight percent of the solvent, with the balance which is mainly water. The solvent introduced into the bubble column reactor 20 can include small quantities of impurities such as, for example, para-tolualdehyde, terephthaldehyde, 4-carboxybenzaldehyde (4- CBA), benzoic acid, para-toluic acid, para-toluic aldehyde, alpha-bromo-para-toluic acid, isophthalic acid, phthalic acid, trimellitic acid, polyaromatics, and / or suspended particulate material. It is preferred that the total amount of impurities in the solvent introduced into the bubble column reactor is less than about 3 weight percent. The catalyst system present in the liquid phase feed stream is preferably a homogeneous liquid phase catalyst system capable of promoting oxidation (including partial oxidation) of the oxidizable compound. More preferably, the catalyst system comprises at least one multivalent transition metal. Still more preferably, the multivalent transition metal comprises cobalt. Even more preferably, the catalyst system comprises cobalt and bromine. Most preferably, the catalyst system comprises cobalt, bromine and manganese. When the cobalt is present in the catalyst system, it is preferred for the amount of cobalt present in the liquid phase feed stream to be such that the concentration of cobalt in the liquid phase of the reaction medium 36 is maintained in the range of about 300 to about 6,000 parts per million by weight (ppmw), more preferably in the range of approximately 700 to about 4,200 ppmw, and much more preferably in the range of 1,200 to 3,000 ppmw. When the bromine is present in the catalyst system, it is preferred that the amount of bromine present in the liquid phase feed stream is such that the concentration of bromine in the liquid phase of the reaction medium 36 is maintained in the range of about 300 to about 5,000 ppmw, more preferably in the range of about 600 to about 4,000 ppmw, and most preferably in the range of 900 to 3,000 ppmw. When manganese is present in the catalyst system, it is preferred that the amount of manganese present in the liquid phase feed stream is such that the concentration of manganese in the liquid phase of the reaction medium 36 is maintained in the range of about 20 to about 1,000 ppmw, more preferably in the range of about 40 to about 500 ppmw, most preferably in the range of 50 to 200 ppmw. The concentrations of cobalt, bromine, and / or manganese in the liquid phase of the reaction medium 36, provided in the foregoing, are expressed on a time-averaged and averaged-in-volume basis. As used herein, the term "time-averaged" will indicate an average of at least 10 measurements taken equally over a continuous period of at least 100 seconds. As is used in the present, the term "averaged in volume" will denote an average of at least 10 measurements taken in the uniform three-dimensional spacing for a certain volume. The weight ratio of cobalt to bromine (Co: Br) in the catalyst system introduced into the reaction zone 28 is preferably in the range of about 0.25: 1 to about 4: 1, more preferably in the range of about 0.5: 1 to about 3: 1, and much more preferably in the range of 0.75: 1 to 2: 1. The weight ratio of cobalt to manganese (Co: Mn) in the catalyst system introduced into the reaction zone 28 is preferably in the range of from about 0.3: 1 to about 40: 1, more preferably in the range of about 5: 1 to about 30: 1, and much more preferably in the range of 10: 1 to 25: 1. The liquid phase feed stream introduced into the bubble column reactor 20 may include small amounts of impurities such as, for example, toluene, ethylbenzene, para-tolualdehyde, terephthalaldehyde, 4-carboxybenzaldehyde (4-CBA), benzoic acid, para-toluic acid, para-toluic aldehyde, alpha bromo paratoluic acid, isophthalic acid, phthalic acid, trimellitic acid, polyaromatics, and / or suspended particulate. When the bubble column reactor 20 is Used for the production of terephthalic acid, meta-xylene and ortho-xylene are also considered impurities. It is preferred that the total amount of impurities in the liquid phase feed stream introduced into the bubble column reactor 20 is less than about 3 weight percent. Although FIG. 1 illustrates an embodiment wherein the oxidizable compound, the solvent, and the catalyst system are mixed together and introduced into the bubble column reactor 20 as a feed stream alone, in an alternative embodiment of the present invention, the oxidizable compound , the solvent, and the catalyst can be separately introduced into the bubble column reactor 20. For example, it is possible to feed a stream of pure para-xylene into the bubbling column reactor 20 via a separate inlet of the reactor. (s) solvent (s) and catalyst inlet (s). The predominantly gas phase oxidant stream introduced into the bubble column reactor 20 via the oxidant sprayer tube 34 comprises molecular oxygen (02). Preferably, the oxidant stream comprises in the range of about 5 to about 40 mole percent molecular oxygen, more preferably in the range of about 15 to about 30 mole percent molecular oxygen, and much more preferably in the range of 18 to 24 mole percent molecular oxygen. It is preferred that the balance of the oxidant stream be comprised primarily of a gas or gases, such as nitrogen, that are inert to oxidation. More preferably, the oxidant stream consists essentially of molecular oxygen and nitrogen. Most preferably, the oxidant stream is dry air comprising about 21 mole percent molecular oxygen and about 78 to about 81 mole percent nitrogen. In an alternative embodiment of the present invention, the oxidant stream may comprise substantially pure oxygen. With reference again to the IG. 1, the bubble column reactor 20 is preferably equipped with a reflux distributor 42 positioned above an upper surface 44 of the reaction medium 36. The reflux distributor 42 is operable to introduce droplets of a reflux stream predominantly in the liquid phase in the decoupling zone 30 by any means of droplet formation known in the art. More preferably, the reflux manifold 42 produces a spray of droplets directed downward towards the upper surface 44 of the reaction medium 36. Preferably, this downward spray of the droplets affects (i.e., couples and influences) at least about 50 percent of the maximum horizontal cross-sectional area of the decoupling zone 30. More preferably, the spray of droplets affects at least about 75 percent of the maximum horizontal cross-sectional area of the decoupling zone 30. Much more preferably, the spray of droplets affects at least 90 percent of the maximum horizontal cross-sectional area of the decoupling zone 30. This downwardly flowing liquid reflux can help prevent foaming at or above the upper surface 44 of the reaction medium 36 and also the decoupling of any liquid or suspension droplets carried in the upwardly moving gas flowing to the gas outlet 40 can help. In addition, the reflux of liquid can serve to reduce the amount of particulate materials and potentially precipitating compounds ( for example dissolved benzoic acid, para-toluic acid, 4-CBA, terephthalic acid and metal salts of catalyst) exiting in the gaseous effluent removed from the decoupling zone 30 via the gas outlet 40. Furthermore, the introduction of reflux droplets in the decoupling zone 30 can, by a distillation action, be used to adjust the composition of the gaseous effluent withdrawn via the gas outlet 40. The reflux stream of liquid introduced into the bubbling column reactor 20 via the Reflux dispenser 42 preferably has approximately the same composition as the solvent component of the liquid phase feed stream introduced into the bubbling column reactor 20 via the feed inlets 32a, b, c, d. Thus, it is preferred that the reflux current of the liquid comprises an acid and water component. The acid component of the reflux stream is preferably an organic monocarboxylic acid of low molecular weight having 1-6 carbon atoms, more preferably 2 carbon atoms. Most preferably, the acid component of the reflux stream is acetic acid. Preferably, the acid component constitutes at least about 75 weight percent of the reflux stream, more preferably at least about 80 weight percent of the reflux stream, and most preferably 85 to 98 weight percent. of the reflux stream, with the rest being water. Because the reflux stream typically has substantially the same composition as the solvent in the liquid phase feed stream, when this description refers to the "total solvent" introduced into the reactor, such a "total solvent" will include both the reflux as the solvent portion of the feed stream. During the oxidation in liquid phase in the reactor of bubbling column 20, it is preferred that the feed, oxidant, and reflux streams are substantially continuously introduced into the reaction zone 28, as long as the gas effluent and slurry streams are substantially continuously removed from each other. the reaction zone 28. As used herein, the term "substantially continuously" will mean during a period of at least 10 interrupted hours for less than 10 minutes. During oxidation, it is preferred that the oxidizable compound (eg, para-xylene) be substantially continuously introduced into the reaction zone 28 in a proportion of at least about 8,000 kilograms per hour, more preferably in a proportion of the range of about 13,000 to about 80,000 kilograms per hour, still more preferably in the range of about 18,000 to about 50,000 kilograms per hour, and most preferably in the range of 22,000 to 30,000 kilograms per hour. Although it is generally preferred that the flow rates of the incoming feed, oxidant, and reflux streams be substantially stable, it is now noted that one embodiment of the present invention contemplates pulsing the feed, oxidant, and / or reflux stream. incoming in order to improve mixing and mass transfer. When the feed stream, oxidant and / or Incoming reflux is introduced in a pulsed form, it is preferred that its flow expenses vary within about 0 to about 500 percent of the permanent state flow expenses recited herein, more preferably within about 30 to about 200 percent of the permanent state flow expenses cited herein, and much more preferably within 80 to 120 percent of the permanent state flow expenses cited herein. The average reaction space-to-time ratio (STR) in the bubble column oxidation reactor 20 is defined as the mass of the oxidizable compound feed per unit volume of the reaction medium 36 per unit time (eg, kilograms). of para-xylene feed per cubic meter per hour). In conventional use, the amount of the oxidizable compound not converted to product would typically be subtracted from the amount of the oxidizable compound in the feed stream before calculating the STR. However, conversions and yields are typically high for many of the oxidizable compounds preferred herein (for example para-xylene) and it is convenient to define the term herein as set forth in the foregoing. For reasons of capital cost and operating inventory among others, it is generally preferred that the reaction be conducted with a high STR. However, the conduction of the reaction in increasingly higher STR can affect the quality or yield of partial oxidation. The bubble column reactor 20 is particularly useful when the STR or oxidizable compound (eg, para-xylene) is in the range of about 25 kilograms per cubic meter per hour to about 400 kilograms per cubic meter per hour, more preferably in the range of about 30 kilograms per cubic meter per hour to about 250 kilograms per cubic meter per hour, still more preferably from about 35 kilograms per cubic meter per hour to about 150 kilograms per cubic meter per hour and much more preferably in the range from 40 kilograms per cubic meter per hour kilograms per cubic meter per hour to 100 kilograms per cubic meter per hour. The oxygen-STR in the bubbling column oxidation reactor 20 is defined as the weight of the molecular oxygen consumed per unit volume of the reaction medium 36 per unit time (eg kilograms of molecular oxygen consumed per cubic meter per hour). For reasons of capital cost and solvent oxidant consumption, among others, it is generally preferred that the reaction be conducted with a high oxygen-STR. However, the conduction of the reaction in oxygen-STR increased more it eventually reduces the quality or yield of partial oxidation. Without being related by theory, it is stated that this possibly relates to the molecular oxygen transfer rate of the gas phase in the liquid in the interfacial surface area and consequently in the liquid in volume. A too high oxygen-STR possibly leads to a too low dissolved oxygen content in the liquid phase by volume of the reaction medium. The global-average-oxygen-STR is defined herein as the weight of all oxygen consumed in the entire volume of the reaction medium 36 per unit time (for example kilograms of molecular oxygen consumed per cubic meter per hour). The bubble column reactor 20 is particularly useful when the global-average-oxygen-STR is in the range of approximately 25 kilograms per cubic meter per hour approximately 400 kilograms per cubic meter per hour, more preferably in the range of approximately 30 kilograms per hour. cubic meter per hour to approximately 250 kilograms per cubic meter per hour, still more preferably from approximately 35 kilograms per cubic meter per hour to approximately 150 kilograms per cubic meter per hour, and much more preferably in the range of 40 kilograms per cubic meter per cubic meter per hour hour 1 100 kilograms per cubic meter per hour.

During oxidation in the bubble column reactor 20, it is preferred that the mass flow rate ratio of the total solvent (from both the feed and reflux streams) to the mass flow rate of the oxidizable compound entering the Reaction zone 28 is maintained in the range of about 2: 1 to about 50: 1, more preferably in the range of about 5: 1 to about 40: 1, and most preferably in the range of 7.5: 1 to 25: 1. Preferably, the ratio of the mass flow rate of the solvent introduced into the feed stream portion to the mass flow rate of the solvent introduced as part of the reflux stream is maintained in the range of about 0.5: 1 to the flow of any reflux stream whatever, more preferably in the range of about 0.5: 1 to about 4: 1, still more preferably in the range of about 1: 1 to about 2: 1, and most preferably in the range of 1.25 : 1 to 1.5: 1. During the liquid phase oxidation in the bubble column reactor 20 it is preferred that the oxidant stream be introduced into the bubble column reactor 20 in an amount that provides molecular oxygen in some way exceeding the stoichiometric oxygen demand. The amount of excess molecular oxygen required for best results with a particular oxidizable compound affects the complete economy of the liquid phase oxidation. During the oxidation of the liquid phase in the bubble column reactor 20, it is preferred that the ratio of the mass flow expense of the oxidant stream to the mass flow rate of the oxidizable organic compound (eg, para-xylene) enter reactor 20 is maintained in the range of about 0.5: 1 to about 20: 1, more preferably in the range of about 1: 1 to about 10: 1, and most preferably in the range of 2: 1 to 6: 1. With reference again to FIG. 1, the feed, oxidant, and reflux streams introduced into the bubble column reactor 20 cooperatively form at least a portion of the multi-phase reaction medium 36. The reaction medium 36 is preferably a three phase medium comprising a solid phase, a liquid phase, and a gas phase. As mentioned above, the oxidation of the oxidizable compound (for example, para-xylene) takes place predominantly in the liquid phase of the reaction medium 36. Thus, the liquid phase of the medium 36 comprises dissolved oxygen and the oxidizable compound. The exothermic nature of the oxidation reaction that takes place in the bubble column reactor causes a portion of the solvent (eg, acetic acid and water) introduced via the feed inputs 32a, b, c, d boil / vaporize. Thus, the gas phase of the reaction medium 36 in the reactor 20 is formed mainly of vaporized solvent and a non-reacted, undissolved portion of the oxidant stream. Prior oxidation reactors employ heat exchange tubes / fins to heat or cool the reaction medium. However, such heat exchange structures may be undesirable in the inventive reactor and the process described herein. Thus, it is preferred that the bubble column reactor 20 includes substantially no surface contacting the reaction medium 36 and exhibits a time-averaged heat flux greater than 30,000 watts per square meter. The concentration of dissolved oxygen in the liquid phase of the reaction medium 36 is a dynamic balance between the mass transfer ratio of the gas phase and the proportion of the reagent consumption within the liquid phase (ie it is not simply adjusted by the partial pressure of molecular oxygen in the supply gas phase, although this is a factor in the proportion of dissolved oxygen supply and affects the upper limiting concentration of dissolved oxygen). The amount of dissolved oxygen varies locally, being higher near the interfaces of. bubble. Overall, the amount of dissolved oxygen it depends on the balance of supply and demand factors in regions other than the reaction medium 36. Temporarily, the amount of dissolved oxygen depends on the uniformity of the gas and liquid mixture relative to the chemical consumption ratios. In the design to properly match the supply and demand for dissolved oxygen in the liquid phase of the reaction medium 36, it is preferred that the volume-averaged and volume-averaged oxygen concentration in the liquid phase of the reaction medium 36 be maintained above. of about 1 molar ppm, more preferably in the range of about 4 to about 1,000 molar ppm, still more preferably in the range of about 8 to about 500 molar ppm, and most preferably in the range of 12 to 120 molar ppm. The liquid phase oxidation reaction carried out in the bubble column reactor 20 is preferably a precipitation reaction that generates solids. More preferably, the liquid phase oxidation carried out in the bubble column reactor causes at least about 10 weight percent of the oxidizable compound (eg, para-xylene) introduced into the reaction zone 28 to form a solid compound (e.g., particles of crude terephthalic acid) in the reaction medium 36. Still more preferably, the oxidation in The liquid phase causes at least about 50 weight percent of the oxidizable compound to form a solid compound in the reaction medium 36. Much more preferably, the liquid phase oxidation causes at least 90 weight percent of the oxidizable compound to form a solid compound in the reaction medium 36. It is preferred that the total amount of solids in the reaction medium 36 be greater than about 3 weight percent on a time averaged and averaged basis in volume. More preferably, the total amount of solids in the reaction medium 36 is maintained in the range of about 5 to about 40 weight percent, still more preferably in the range of about 10 to about 35 weight percent, and much more preferably in the range of 15 to 30 weight percent. It is preferred that a substantial portion of the oxidation product (e.g., terephthalic acid) produced in the bubble column reactor 20 be present in the 3ß reaction medium as solids, as opposed to the remainder dissolved in the liquid phase of the medium. reaction 36. The amount of the solid phase oxidation product present in the reaction medium 36 is preferably at least about 25 weight percent of the total oxidation product (solid and liquid phase) in the reaction medium 36, more preferably at least approximately 75 percent by weight of the total oxidation product in the reaction medium 36, and most preferably at least 95 percent by weight of the total oxidation product in the reaction medium 36. The numerical ranges provided in the above for the amount of solids in the reaction medium 36 apply to the permanent state operation of substantially the bubble column 20 for a substantially continuous period of time, not starting, stopping, or sub-optimal operation of the bubble column reactor 20. The amount of solids in the reaction medium 36 is determined by a gravimetric method. In this gravimetric method, a representative portion of suspension is removed from the reaction medium and weighed. Under the conditions that effectively maintain the present full solid-liquid partition within the reaction medium, the free liquid is removed from the solids portion by sedimentation or filtration, effectively without loss of the precipitated solids and with less than about 10 percent. percent of the initial liquid mass that remains with the solids portion. The remaining liquid in the solids evaporates to dryness, effectively without the sublimation of solids. The remaining portion of solids is weighed. The ratio of the weight of the solids portion to the weight of the original suspension portion is the fraction of solids, typically expressed as a percentage.

The precipitation reaction carried out in the column reactor 20 can cause fouling (ie, accumulation of solids) on the surface of certain rigid structures that make contact with the reaction medium 36. Thus, in one embodiment of the present invention, it is preferred that the bubble column reactor comprises substantially non-internal heat exchange, agitation, or deflection structures in the reaction zone 28 because such structures could be prone to fouling. If the internal structures are present in the reaction zone 28, it is desirable to avoid the internal structures having external surfaces that include a significant amount of flat surface area facing upwards because such flat surfaces facing upwards would be highly prone. to fouling. Thus, if any of the internal structures are present in the reaction zone 28, it is preferred that less than about 20 percent of the exposed external surface area facing upward total of such internal structures be formed by substantially flat surfaces inclined less than about 15 degrees from the horizontal. With reference again to FIG. 1, the physical configuration of the bubble column reactor 20 helps to provide the optimized oxidation of the compound oxidizable (for example, para-xylene) with minimal impurity generation. It is preferred for the elongate reaction section 24 of the container shell 22 to include a substantially cylindrical main body 46 and a lower head 48. The upper end of the reaction zone 28 is defined by a horizontal plane 50 extending through of the upper part of the cylindrical body 46. A lower end 52 of the reaction zone 28 is defined by the lower internal surface of the lower head 48. Typically, the lower end 52 of the reaction zone 28 is located near the hole for the outlet of the suspension 38. Thus, the elongated reaction zone 28 defined within the bubble column reactor 20 has a maximum length "L" measured from the upper end 50 to the bottom end 52 of the reaction zone 29 along the elongation axis of the cylindrical main body 46. The length "L" of the reaction zone 28 is preferably in the range of about 10 to about 100 meter s, more preferably in the range of about 20 to about 75 meters, and much more preferably in the range of 25 to 50 meters. The reaction zone 28 has a maximum diameter (width) "D" which is typically equal to the maximum internal diameter of the cylindrical middle body 46. The maximum diameter "D" of the reaction zone 28 is preferably in the range of about 1. at about 12 meters, more preferably in the range of about 2 to about 10 meters, and much more preferably in the range of 3.1 to about 9 meters, and much more preferably in the range of 4 to 8 meters. In a preferred embodiment of the present invention, the reaction zone 28 has a length-to-diameter ratio "L: D" in the range of about 6: 1 to about 30: 1. Still more preferably, the reaction zone 28 has an L: D ratio in the range of about 8: 1 to about 20: 1. Most preferably, the reaction zone 28 has an L: D ratio in the range of 9: 1 to 15: 1. As discussed in the foregoing, the reaction zone 28 of the bubble column reactor 20 receives the multi-phase reaction medium 36. The reaction medium 36 has a bottom end coincident with the lower end 52 of the reaction zone. 28 and an upper end located on the upper surface 44. The upper surface 44 of the reaction medium 36 is defined along a horizontal plane that is cut through the reaction zone 28 at a location where the contents of the zone of reaction 28 transits from a continuous state in gas phase to a continuous state of liquid phase. The upper surface 44 is preferably placed in the vertical location where the gas containment averaged in local time from a horizontal cut thin of the contents of the reaction zone 28 is 0.9. The reaction medium 36 has a maximum height "H" measured between its upper and lower ends. The maximum width "W" of the reaction medium 36 is typically equal to the maximum diameter "D" of the cylindrical middle body 46. During the liquid phase oxidation in the bubbling column reactor 20, it is preferred that H be maintained approximately 60 to about 120 percent L, more preferably about 80 to about 110 percent L, and much more preferably 85 to 100 percent L. In a preferred embodiment of the present invention, the reaction medium 36 has a Height to width ratio "H: W" greater than approximately 3: 1. More preferably, the reaction medium 36 has an H: W ratio in the range of about 7: 1 to about 25: 1. Still more preferably, the reaction medium 36 has an H: W ratio in the range of about 8: 1 to about 20: 1. Most preferably, the reaction medium 36 has an H: ratio in the range of 9: 1 to 15: 1. In one embodiment of the invention, L = H and D = W so that several dimensions or relationships provided herein for L and D also apply to H and W, and vice versa. The relatively high L: D and H: W ratios provided in accordance with one embodiment of the invention can contribute to several important advantages of the system inventive. As discussed in further detail below, it has been found that the higher L: D and H: W ratios, as well as some other features discussed below, can promote beneficial vertical gradients in molecular oxygen concentrations and / or oxidizable compound ( for example, para-xylene) in the reaction medium 36. Contrary to conventional wisdom, which would favor a well-mixed reaction medium with relatively uniform concentrations throughout, it has been found that vertical stage formation of oxygen and / or concentrations Oxidizable compound facilitates a more effective and economical oxidation ratio. The oxygen minimization and the oxidizable compound concentrations near the top of the reaction medium 36 can help the loss of unreacted oxygen and the unreacted oxidizable compound through the upper gas outlet 40. However, if the of the oxidizable compound and the unreacted oxygen are low throughout the reaction medium 36, then the proportion and / or selectivity of the oxidation is reduced. Thus, it is preferred that the concentrations of molecular oxygen and / or the oxidizable compound are significantly higher near the bottom of the reaction medium 36 than near the top of the reaction medium 36. In addition, the L: D and H ratios: high cause the pressure at the bottom of the reaction medium 36 is substantially greater than the pressure at the top of the reaction medium 36. This vertical pressure gradient is a result of the height and density of the reaction medium 36. An advantage of this Vertical pressure gradient is that the elevated pressure at the bottom of the vessel directs more oxygen solubility and mass transfer than would otherwise be achievable at comparable temperatures and pressures from the top in the lower reactors. Thus, the oxidation reaction can be carried out at lower temperatures that would be required in a lower vessel. When the bubble column reactor 20 is used for the partial oxidation of para-xylene to crude terephthalic acid (CTA), the ability to operate at lower reaction temperatures with the same or better proportions of oxygen mass transfer has a number of advantages For example, low temperature oxidation of para-xylene reduces the amount of solvent burned during the reaction. As discussed in further detail below, oxidation at low temperatures also favors the formation of easily dissolved, loose-bound CTA particles of small, high surface area, which can be subjected to more economic purification techniques than dense CTA particles. , of low, large surface area, produced by the oxidation processes of conventional high temperature. During oxidation in the reactor 20, it is preferred that the temperature averaged and averaged in volume of the reaction medium 36 be maintained in the range of about 125 to about 200 ° C, more preferably in the range of about 140 to about 180. ° C, and much more preferably in the range of 150 to 170 ° C. The pressure of the top of the reaction medium 36 is preferably maintained in the range of about 1 to about 20 bar gauge (barg), more preferably in the range of about 2 to about 12 barg, and much more preferably in the range from 4 to 8 barg. Preferably, the pressure difference between the top of the reaction medium 36 and the bottom of the reaction medium 36 is in the range of about 0.4 to about 5 bars, more preferably the pressure difference is in the range of about 0.7 to about 3 bars, and much more preferably the pressure difference is at 2 bar. Although it is generally preferred that the pressure of the top portion of the reaction medium 36 be maintained at a relatively constant value, one embodiment of the present invention contemplates pressing the pressure of the top portion to facilitate improved mixing and / or transfer. of dough in the middle of reaction 36. When the pressure at the top is depressed, it is preferred that the pulsed pressures vary between about 60 to about 140 percent of the pressure of the top portion of permanent state recited herein, more preferably between about 85 and about 115 percent of the pressure of the top portion of permanent state recited herein, and most preferably between 95 and 105 percent of the pressure of the top portion of permanent state recited herein. An additional advantage of the high L: D ratio of the reaction zone 28 is that it can contribute to an increase in the average surface velocity of the reaction medium 36. The term "surface velocity" and "surface gas velocity", as are used herein with reference to the reaction medium 36, will indicate the volumetric flow rate of the gas phase of the reaction medium 36 at an elevation in the reactor divided by the horizontal cross-sectional area of the reactor at that elevation. The increased surface velocity provided by the high L: D ratio of the reaction zone 28 can promote local mixing in increasing gas stopping of the reaction medium 36. The averaged time velocities of the reaction medium 36 at a height of a quarter, half height, and / or three quarters of height of the middle of reaction 36 are preferably larger than about 0.3 meters per second, more preferably in the range of about 0.8 to about 5 meters per second, still more preferably in the range of about 0.9 to about 4 meters per second, and most preferably in the range of interval of 1 to 3 meters per second. With reference again to FIG. 1, the decoupling section 26 of the bubble column reactor 20 is simply an enlarged portion of the container shell 22 located immediately above the reaction section 24. The decoupling section 26 reduces the velocity of the flowing gas phase up in the bubble column reactor 20 as the gas phase rises above the upper surface 44 of the reaction medium 36 and approaches the outlet of the gas 40. This reduction in the upward velocity of the gas phase it helps to facilitate the removal of the liquids and / or solids transported in the gas phase that flows upwards and in this way reduces the undesirable loss of certain components present in the liquid phase of the reaction medium 26. The decoupling section 26 preferably includes a generally frustroconical transition wall 54, a broad generally cylindrical side wall 56, and an upper head 58. The narrow lower end of the transition wall 54 engages the upper part of the cylindrical middle body 46 of the reaction section 24. The broad upper end of the transition wall 54 engages the bottom of the wall wide side 56. It is preferred that the transition wall 54 extend up and down from its narrow lower end at an angle in the range of about 10 to about 70 degrees from vertical, more preferably in the range of about 15 about 50. degrees of vertical, and much more preferably in the range of 15 to 45 degrees of vertical. The wide side wall 56 has a maximum diameter "X" which is generally larger than the maximum diameter "D" of the reaction section 24, although when the upper portion of the reaction section 24 has a diameter smaller than the diameter full maximum of the reaction section 24, then X may actually be smaller than D. In a preferred embodiment of the present invention, the ratio of the diameter of the wide side wall 56 to the maximum diameter of the reaction section 24"X: D "is in the range of about 0.8: 1 to about 4: 1, much more preferably in the range of 1.1: 1 to 2: 1. The upper head 58 engages the upper part of the wide side wall 56. The upper head 58 is preferably a head member. generally elliptical defining a central hole that allows the gas to escape from the decoupling zone 30 via the gas outlet 40. Alternatively, the upper head 58 may be of any shape, including conical. The decoupling zone 30 has a maximum height "Y" measured from the top 50 of the reaction zone 28 to the uppermost portion of the decoupling zone 30. The ratio of the length of the reaction zone 28 to the height of the decoupling zone 30"L:" is preferably in the range of about 2: 1 to about 24: 1, more preferably in the range of about 3: 1 to about 20: 1 and most preferably in the range of 4 : 1 to 16: 1. With reference now to FIGS. 1-5, the location and configuration of the oxidant spray tube 34 will now be discussed in more detail. FIGS. 2 and 3 show that the oxidant spray tube 34 may include a ring member 60, a cross member 62, and a pair of oxidant inlet passages 64a, b. Conveniently, these oxidant inlet passages 64a can enter the container at an elevation above the ring member 60 and then rotate downwardly as shown in FIGS. 2 and 3. Alternatively, an oxidant inlet duct 64a, b may enter the container below the ring member 60 or above around the same horizontal plane as the ring member 60. Each oxidant inlet conduit 64a, b includes a first end coupled to a respective oxidant inlet 66a, b formed in the container shell 22 and a second end fluidly coupled to the ring member 60. The member ring 60 is preferably formed of ducts, more preferably of a plurality of sections of straight ducts, and most preferably a plurality of sections of straight tubes, rigidly coupled to each other to form a tubular polygonal ring. Preferably, the ring member 60 is formed of at least 3 straight tube sections, more preferably 6 to 10 tube sections, and most preferably 8 tube sections. Accordingly, when the ring member 60 is formed of 8 tube sections, it has a generally octagonal configuration. The cross member 62 is preferably formed of a substantially straight tube section which is fluidly coupled to and extends diagonally between the opposed tube sections of the ring member 60. The tube section used for the cross member 63 preferably has substantially the same diameter as the tube sections used to form the ring member 60. It is preferred that the tube sections constituting the oxidant inlet passages 64a, b, the ring member 60, and the cross member 62 have a larger nominal diameter what about 0.1 meters, more preferably in the range of about 0.2 to about 2 meters, and much more preferably in the range of 0.25 to 1 meter. As perhaps better illustrated in FIG. 3, the ring member 60 and the cross member 62 each have a plurality of upper oxidant holes 68 for discharging the oxidant stream upwardly in the reaction zone 28. As perhaps best illustrated in FIG. 4, the ring member 60 and / or the cross member 62 may have one or more lower oxidant orifices 70 for discharging the oxidant stream downwardly in the reaction zone 28. The lower oxidant orifices 70 may also be used for discharging liquids and / or solids that could be introduced into the ring member 60 and / or the cross member 62. In order to prevent solids from accumulating within the oxidant spray tube 34, a stream of liquid can be continuously or periodically passed through the spray tube 34 to clean any of the accumulated solids. With reference again to FIGS. 1-4, during oxidation in the bubbling column reactor 20, the oxidant streams are passed through the oxidant inputs 66a, b and in the oxidant inlet conduits 64a, b, respectively. The oxidant streams are then transported via the inlet conduits Oxidant 64a, b to ring member 60. Once the oxidant stream has entered ring member 60, the oxidant stream is distributed throughout all internal volumes of ring member 60 and cross member 62. The oxidant stream is then passed out of the oxidant spray tube 34 and into the reaction zone 28 via the upper and lower oxidant orifices 68, 70 of the ring member 60 and the cross member 62. The outputs of the upper oxidant holes 68 are laterally spaced from one to the other and placed at substantially the same elevation in the reaction zone 28. Thus, the outlets of the upper oxidant orifices 68 are generally located along a substantially horizontal plane defined by the part upper of the oxidant spray pipe 34. The outlets of the lower oxidant holes 70 are laterally spaced from one another and placed at substantially the same elevation in the reaction zone 28. Thus, the outlets of the lower oxidant orifices 70 are generally located along a substantially horizontal plane defined by the bottom of the oxidant sprayer tube 34. In one embodiment of the present invention, the oxidant sprayer tube 34 has at least about 20 upper oxidant holes 68 formed therein. the same. Plus preferably, the oxidant spray tube 34 has in the range of about 40 to about 800 upper oxidant holes formed therein. Much more preferably, the oxidant spray tube 34 has in the range of from 60 to 400 upper oxidant ports 68 formed therein. The oxidant spray tube 34 preferably has at least about 1 lower oxidant hole 70 formed therein. More preferably, the oxidant spray tube 34 has in the range of about 2 to about 40 lower oxidant holes 70 formed therein. Much more preferably the oxidant spray tube 34 has the range of 8 to 20 lower oxidant holes 70 formed therein. The ratio of the number of upper oxidant orifices 68 to the lower oxidant orifices 70 in the oxidant spray tube 34 is preferably in the range of about 2: 1 to about 100: 1, more preferably in the range of about 5: 1. at about 25: 1, and much more preferably in the range from 8: 1 to 15: 1. The diameters of substantially all upper and lower oxidant orifices 68, 70 are preferably substantially the same, so that the ratio of the volumetric flow rate of the oxidant stream leaving the upper and lower orifices 68, 70 is substantially the same as the ratios, given in the foregoing, for the relative number of upper and lower oxidant orifices 68, 70. FIG. 5- illustrates the direction of the oxidant discharge from the upper and lower oxidant orifices 68, 70. With reference to the upper oxidant orifices 68, it is preferred that at least a portion of the upper oxidant orifices discharges the oxidant at an angle "A" that is oblique from the vertical. It is preferred that the percentage of the upper oxidant orifices 68 be oblique from the vertical by the angle "A" to be in the range of about 30 to about 90 percent, more preferably in the range of about 50 to about 80 percent , still more preferably in the range of 60 to 75 percent, and much more preferably approximately 67 percent. The angle "A" is preferably in the range of about 5 to about 60 degrees, more preferably in the range of about 10 to about 45 degrees, and most preferably in the range of 15 to 30 degrees. As for the lower oxidant orifices 70, it is preferred that substantially all of the lower oxidant orifices 70 be located near the most bottom portion of the ring member 60 and / or the cross member 62. Thus, any of the liquids and / or solids that may have intentionally entered the tube Oxidizer sprayer 34 can be easily discharged from the oxidant spray tube 34 via the lower oxidant orifices 70. Preferably, the lower oxidant orifices 70 discharge the oxidant stream downward at a substantially vertical angle. For purposes of this description, an upper oxidant orifice may be any orifice that discharges a stream of oxidant in a generally upward direction (i.e., at an angle above the horizontal), and a lower oxidant orifice may be any orifice that discharges a stream of oxidant in a generally downward direction, (i.e. at an angle below the horizontal). In many conventional bubble column reactors containing a multi-phase reaction medium, substantially all of the reaction medium located below the oxidant spray tube (or other mechanism for introducing the oxidant stream into the reaction zone) has a value of very low gas containment. As is known in the art, "gas containment" is simple the volume fraction of a multi-phase medium that is in the gaseous state. Low gas containment zones in a medium can also be referred to as "deaired" zones. In many conventional suspension bubble column reactors, a significant portion of the total volume of the reaction medium is located below the oxidant spraying tube (or other mechanism for introducing the oxidant stream in the reaction zone). Thus, a significant portion of the reaction medium present at the bottom of conventional bubble column reactors is not aerated. It has been found that minimizing the amount of non-aerated zones in a reaction medium subjected to oxidation in a bubble column reactor can minimize the generation of certain types of undesirable impurities. The non-aerated zones of a reaction medium contain relatively few oxidant bubbles. This low volume of oxidant bubbles reduces the amount of molecular oxygen available for dissolution in the liquid phase of the reaction medium. Thus, the liquid phase in a non-aerated zone of the reaction medium has a relatively low concentration of molecular oxygen. These non-aerated, underfed oxygen zones of the reaction medium have a tendency to promote undesirable side reactions, rather than the desired oxidation reaction. For example, when para-xylene is partially oxidized to form terephthalic acid, insufficient oxygen availability in the liquid phase of the reaction medium can cause the formation of undesirably high amounts of benzoic acid and coupled aromatic rings, which include notably highly undesirable colored molecules known as fluorenones and anthraquinones. According to one embodiment of the present invention, the liquid phase oxidation is carried out in a bubble column reactor configured and operated in such a way that the volume fraction in the reaction medium with low gas containment values it is minimized. This minimization of the non-aerated zones can be quantified by theoretically dividing the entire volume of the reaction medium into 2,000 discrete horizontal cuts of uniform volume. With the exception of the highest and lowest horizontal cuts, each horizontal cut is a discrete volume joined on its sides by the side wall of the reactor and joined on its top and bottom by imaginary horizontal planes. The upper horizontal cut is joined on its bottom by an imaginary horizontal plane and on its upper part by the upper surface of the reaction medium. The lower horizontal cut is joined on its upper part by an imaginary horizontal plane and on its bottom by the lower end of the container. Once the reaction medium has been theoretically divided into 2,000 discrete horizontal cuts of equal volume, the gas containment averaged in time and averaged in volume of each horizontal cut can be determined. When this method of quantifying the amount of untreated areas is employed, it is preferred that the number of horizontal cuts have a gas containment averaged in time and averaged in volume less than 0.1 to be less than 30, more preferably less than 15, still more preferably less than 6, even more preferably less than 4, and much more preferably less than 0.2 It is preferred that the number of horizontal cuts have a gas containment less than 0.2 to be less than 80, more preferably less than 40, still more preferably less than 20, even more preferably less than 12, and much more preferably less 5. It is preferred that the number of horizontal cuts have a gas containment less than 0.3 to be less than 120, more preferably less than 80, still more preferably less than 40, even more preferably less than 20, and much more preferably less. 15. With reference again to FIGS. 1 and 2, it has been found that the lowest oxidizing spray tube 34 in the reaction zone 28 provides several advantages, including reducing the amount of the non-aerated zones in the reaction medium 36. Given a height "H" of the reaction medium 36, a length "L" of the reaction zone 28, and a maximum diameter "D" of the reaction zone 28, it is preferred that a majority (ie,> 50 percent by weight) of the oxidant stream is introduced into the reaction zone 28 within about 0.025H, 0.022L, and / or 0.25D of the end, bottom 52 of the reaction zone 28. More preferably, a majority of the oxidant stream is introduced into the reaction zone 28 within about 0.02H, 0.018L, and / or 0.2D from the lower end 52 of the zone 28. Much more preferably, a majority of the oxidant stream is introduced into the reaction zone 28 within 0.015H, 0.013L, and / or 0.15D of the lower end 52 of the reaction zone 28. In the embodiment illustrated in FIG. 2, the vertical distance "Yi" between the lower end 52 of the reaction zone 28 and the outlet of the upper oxidant orifices 68 of the oxidant spray tube 34 is less than about 0.25H, 0.22L, and / or 0.25D , so that substantially all of the oxidant stream enters the reaction zone 28 within about 0.25H, 0.22L, and / or 0.25D from the lower end 52 of the reaction zone 28. More preferably, Yx is less than approximately 0.02H, 0.018L, and / or 0.2D. Much more preferably, Yi is less than 0.015H, 0.013L, and / or 0.15D, but more than 0.005H, 0.004L, and / or 0.06D. FIG. 2 illustrates a tangent line 72 at the location where the bottom edge of the cylindrical body 46 of the container shell 22 joins the upper edge of the elliptical head 48 of the container shell 22. Alternatively, the lower head 48 can be any shape including conical, and the tangent line it is still defined as the bottom edge of the cylindrical body 46. The vertical distance "Y2" between the tangent line 72 and the top of the oxidant sprayer tube 34 is preferably at least about 0.0012H, 0.001L, and / or 0.01D; more preferably at least about 0.005H, 0.004L, and / or 0.05D; and much more preferably at least 0.01H, 0.008L, and / or 0.1D. The vertical distance "Y3" between the lower end 52 of the reaction zone 28 and the outlet of the lower oxidant orifices 70 of the oxidant spray tube 34 is preferably less than about 0.0015H, 0.013L, and / or 0.15D; more preferably less than about 0.012H, 0.01L, and / or 0.1D; and much more preferably less than 0.01H, 0.008L, and / or 0.075D, but more than 0.003H, 0.002L, and / or 0.025D. In a preferred embodiment of the present invention, the orifices discharging the oxidizing stream and the feed stream in the reaction zone are configured such that the amount (by weight) of the oxidant or the feed stream discharged from an orifice are directly proportionate to the open area of the hole. Thus, for example, if 50 percent of the cumulative open area defined by all the oxidant orifices is located within 0.15D of the bottom of the reaction zone, then 50 percent by weight of the oxidant stream enters the reaction zone within 0.15D from the bottom of the reaction zone and vice versa. In addition to the advantages provided in minimizing the non-aerated zones (i.e. areas with low gas containment) in a reaction medium 36, it has been found that oxidation can be increased by maximizing the gas containment of the entire reaction medium. The reaction medium 36 preferably has gas containment averaged over time and averaged in volume of at least about 0.4, more preferably in the range of about 0.6 to about 0.9, and much more preferably in the range of 0.65 to 0.85. Various physical and operational attributes of the bubble column reactor 20 contribute to the high gas containment discussed above. For example, for a given reactor size and oxidant current flow, the high L: D ratio of the reaction zone 23 produces a lower diameter which increases the surface velocity in the reaction medium 36 which in turn increases the gas containment. Additionally, the current diameter of a bubble column and the ratio L: D are known to influence the average gas stop even for a given constant surface velocity. In addition, the minimization of the non-aerated areas, particularly at the bottom of the reaction zone 28, contributes to an increased gas containment value. In addition, the pressure of the Top part and the mechanical configuration of the bubble column reactor can affect the operating stability at the high surface velocities and the gas containment values disclosed herein. In addition, the inventors have discovered the importance of operation with optimized top-part pressure to obtain increased gas containment and increased mass transfer. It might appear that the operation with a lower top pressure, which reduces the solubility of molecular oxygen according to a Law Henry effect, would reduce the mass transfer rate of the molecular oxygen from the gas to the liquid. In a mechanically agitated container, such is typically the case due to the levels of aeration and the mass transfer ratios are called by the design of the agitator and the pressure of the top part. However, in a bubble column reactor according to a preferred embodiment of the present invention, it has been discovered how to use a lower top pressure to cause a given mass of oxidant stream in gas phase to occupy more volume, increase the surface velocity in the reaction medium 36 and in turn increase the gas containment and molecular oxygen transfer rate. The balance between coalescence and dispersion of bubbling is an extremely complicated phenomenon, leading on the one hand to a tendency to foam, which reduces the internal circulation proportions of the liquid phase and which may require, very large decoupling zones, and on the other hand a tendency to more few, very large bubbles that give a lower gas containment and lower mass transfer ratio of the oxidant stream to the liquid phase. Concerning the liquid phase, its composition, density, viscosity and surface tension, among other factors, are known to interact in a very complicated way to produce very complicated results even in the absence of a solid phase. For example, laboratory researchers have found it useful to qualify whether "water" is drinking water, distilled water, or deionized water, when they report and evaluate observations for even simple water-air bubble columns. For complex mixtures in the liquid phase and for the addition of a solid phase, the degree of complexity is further increased. The surface irregularities of the individual solids particles, the average solids size, the particle size distribution, the amount of solids relative to the liquid phase, and the ability of liquid to wet the surface of the solid among other things, all they are important in their interaction with the liquid phase and the oxidant current in establishing that the bubbling behavior and the flow patterns of natural convention will result. Thus, the ability of the bubble column reactor to operate usefully with the high surface velocities and high gas containment disclosed herein depends, for example, on an appropriate selection of: (1) the composition of the liquid phase of the medium of reaction; (2) the amount and type of the precipitated solids, both of which can be adjusted by reaction conditions; (3) the amount of the oxidant stream fed to the reactor; (4) the pressure of the top part that affects the volumetric flow of the oxidant stream, the stability of the bubbles, and, via the energy balance, the reaction temperature; (5) the reaction temperature by itself, which affects the properties of the fluid, the properties of the precipitated solids, and the specific volume of the oxidant stream; and (6) details of the geometry and mechanics of the reaction vessel, including the L: D ratio. Referring again to FIG. 1, it has been found that the improved distribution of the oxidizable compound (for example, para-xylene) in the reaction medium 36 can be provided by introducing a liquid phase feed stream into the reaction zone 28 at multiple vertically spaced locations. Preferably, the liquid phase feed stream it is introduced into the reaction zone 28 via at least 3 feed holes, more preferably at least 4 feed holes. As used herein, the term "feed orifices" will indicate the orifices where the liquid phase feed stream is discharged into the reaction zone 28 to be mixed with the reaction medium 36. It is preferred that at least two of the feed holes are vertically spaced from one to the other by at least about 0.5D, more preferably at least about 1.5D, and much more preferably at least 3D. However, it is preferred that the highest feed orifice be spaced vertically from the lowest oxidant orifice but not more than about 0.75H, 0.65L and / or 8D; more preferably no more than about 0.5H, 0.4L and / or 5D; and much more preferably not more than 0.4H, 0.35L and / or 4D. Although it is desirable to introduce the liquid phase feed stream in multiple vertical locations, it has also been found that the improved distribution in the oxidizable compound in the reaction medium 36 is provided if the majority of the liquid phase feed stream is introduced into the liquid phase. half the bottom in the reaction medium 36 and / or the reaction zone 28. Preferably, at least about 75 weight percent of the feed stream in the liquid phase is it enters into the middle of the bottom of the reaction medium 36 and / or the reaction zone 28. Much more preferably at least 90 weight percent of the feed stream in the liquid phase is introduced into the middle of the bottom of the reaction medium 36 and / or the reaction zone 28. Further, it is preferred that at least 30 weight percent of the liquid phase feed stream is introduced into the reaction zone 28 within approximately 1.5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. This lower vertical location where the oxidant stream is introduced into the reaction zone 28 is typically at the bottom of the oxidant spray tube; however, a variety of alternative configurations for introducing the oxidant stream from the reaction zone 28 are contemplated by one embodiment of the present invention. Preferably, at least about 50 weight percent of the liquid phase feed is introduced within about 2.5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. Preferably, at least about 75% by weight of the liquid phase feed stream is introduced within about 5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. Each feed orifice defines an area open through which the feed is discharged. It is preferred that at least about 30 percent of the cumulative open area of all feed inlets be located within approximately 1.5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. Preferably, less about 50 percent of the cumulative open area of all the feed inputs are located within about 2.5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. Preferably, at least about 75 One hundred percent of the cumulative open area of all the feed inputs are located within about 5D of the lowest vertical location where the oxidant stream is introduced into the reaction zone 28. Referring again to FIG. 1, in one embodiment of the present invention, the feed ports 32a, b, c, d are simply a series of holes vertically aligned along the side of the container shell 22. These feed holes preferably have substantially similar diameters. less than about 7 centimeters, more preferably in the range of about 0.25 to about 5 centimeters, and much more preferably in the range of 0.4 to 2 centimeters. The bubble column reactor 20 preferably it is equipped with a system for controlling the flow rate of the liquid phase feed stream outside each feed orifice. Such a flow control system preferably includes an individual flow control valve 74a, b, c, d for each respective feed input 32a, b, c, d. Further, it is preferred that the bubble column reactor 20 be equipped with a flow control system that allows at least a portion of the liquid phase feed stream to be introduced into the reaction zone 28 at a surface velocity of input high of at least about 2 meters per second, more preferably at least about 5 meters per second, still more preferably at least about 6 meters per second, and much more preferably in the range of 8 to 20 meters per second. As used herein, the term "inlet surface velocity" indicates the time-averaged volumetric flow rate of the feed stream outside the feed orifice divided by the area of the feed orifice. Preferably at least about 50 percent of the feed stream is introduced into the reaction zone 28 at a high inlet surface velocity. Much more preferably, substantially all of the feed stream is introduced into the reaction zone 28 at a high input surface velocity. With reference now to FIGS. 6-7, an alternative system for introducing the liquid phase feed stream into the reaction zone 28 is illustrated. In this embodiment, the feed stream is introduced into the reaction zone 28 at four different elevations. Each elevation is equipped with a respective power distribution system 76a, b, c, d. Each feed distribution system 76 includes a middle feed conduit 78 and a manifold 80. Each manifold 80 is provided with at least 2 outlets 82, 84 coupled to the respective insertion conduits 86, 88, which extend into the zone. of reaction 28 of the container shell 22. Each insertion conduit, 86, 88 has a respective feed hole, 87, 89 for discharging the feed stream in the reaction zone 28. Feed holes 87, 89 preferably have substantially similar diameters of less than about 7 centimeters, more preferably in the range of about 0.25 to about 5 centimeters, and much more preferably in the range of 0.4 to 2 centimeters. It is preferred that the feed holes 87, 89 of each feed distribution distribution system 76a, b, b, d are diametrically opposed in order to introduce the feed stream into the reaction zone 28 at the opposite directions3. Furthermore, it is preferred that the diametrically opposed feeding holes 86, 88 of the adjacent feed distribution systems 76 be oriented at 90 ° relative to each other. In operation, the liquid phase feed stream is charged to the medium feed conduit 78 and subsequently enters the manifold 80. The manifold 80 distributes the feed stream uniformly for simultaneous introduction on opposite sides of the reactor 20 via the feed stream. the feed holes 87, 89. FIG. 8 illustrates an alternative configuration wherein each power distribution system 76 is equipped with bayonet tubes 90, 92 different from the insertion conduits 86, 88 (shown in FIG.7). The bayonet tubes, 90, 92 project into the reaction zone 28 and include a plurality of small feed holes 94, 96 for discharging the liquid phase feed into the reaction zone 28. It is preferred that the small feed holes 94, 96 of the bayonet tubes 90, 92 have substantially the same diameters of less than about 50 millimeters, more preferably from about 2 to about 25 millimeters and much more preferably from 4 to 15 millimeters. FIGS. 9-11 illustrate an alternative power distribution system 100. The distribution system feed 100 introduces the liquid phase feed stream to a plurality of vertically spaced and laterally spaced locations without the requirement of multiple penetrations of the side wall of the bubble column replenishment 20. Feed introduction system 100 generally includes a conduit input only 102, a head 104 a plurality of straight distribution tubes 106, a lateral support mechanism 108, and a vertical support mechanism 110. The entry conduit 102 penetrates the side wall of the middle body 46 of the container shell 22. The inlet conduit 102 is fluidly coupled to the head 104. The head 104 distributes the feed stream received from the inlet conduit 102 uniformly between the straight distribution pipes 106. Each distribution pipe 106 has a plurality of feed holes vertically spaced 112a, b, c, d to discharge the power supply in the reaction zone 28. The lateral support mechanism 108 engages each distribution tube 106 and inhibits the relative lateral movement of the distribution tubes 106. The vertical support mechanism 110 is preferably coupled to the lateral support mechanism 108. and to the top of the oxidant spray tube 34. The vertical support mechanism 110 substantially inhibits the vertical movement of the distribution tubes 106 in the reaction zone 28. it prefers that the feed holes 112 have substantially the same diameters as less than about 50 millimeters, more preferably about 2 to about 25 millimeters, and much more preferably 4 to 15 millimeters. The vertical spacing of the feed holes 112 of the feed distribution system 100 illustrated in FIGS. 9-11 may be substantially the same as described in the foregoing, with reference to the power distribution system of FIG. 1. It has been found that the flow patterns of the reaction medium in many bubble column reactors can allow unequal azimuth distribution of the oxidizable compound in the reaction medium, especially when the oxidizable compound is introduced mainly along a side of the reaction medium. As used herein the term "azimuth" will indicate an angle or space around the straight axis of elongation of the reaction zone. As used herein, "straight" will mean within 45 degrees of vertical. In one embodiment of the present invention, the feed stream containing the oxidizable compound (eg, para-xylene) is introduced into the reaction zone via a plurality of azimutically spaced feed orifices. These azimuthally spaced feed holes can help prevent regions of excessively high and excessively low oxidizable compound concentrations in the reaction medium. The various feed introduction systems illustrated in FIGS. 6-11 are examples of systems that provide the appropriate azimuthal spacing of feed holes. With reference again to FIG. 7, in order to quantify the azimuthally spaced introduction of the liquid phase feed stream into the reaction medium, the reaction medium can theoretically be divided into four straight azimuthal quadrants "Qi, Q2, Q3, QX of approximately equal volume. These azimuthal quadrants "Qir Q2r 0.3 / QX are defined by a pair of perpendicular vertical planes of imaginary insertion" P_, P2"that extend beyond the maximum vertical dimension and maximum radial dimension of the reaction medium. When the reaction medium is contained in a cylindrical vessel, the insertion line of the imaginary vertical planes of insertion, Pi, P2 will roughly coincide with the vertical centerline of the cylinder, and each azimuthal quadrant Q?, Q2, Q3, Q4 they will be a generally wedge-shaped vertical volume that have a height equal to the height of the reaction medium. It is preferred that a substantial portion of the oxidizable compound be charged into the reaction medium via the feed holes located at minus two different azimuthal quadrants. In a preferred embodiment of the present invention, no more than about 80 weight percent of the oxidizable compound is discharged into the reaction medium through the feed holes that can be located in an azimuthal quadrant only. More preferably, no more than about 60 percent of the oxidizable compound is discharged into the reaction medium through the feed ports that can be located in an azimuthal quadrant only. Most preferably, no more than 40 weight percent of the oxidizable compound is discharged into the reaction medium through the feed holes that can be located in an azimuthal quadrant only. These parameters for the azimuth distribution of the oxidizable compound are measured when the azimuthal quadrants are azimuthally oriented such that the maximum possible amount of the oxidizable compound is being discharged in one of the azimuthal quadrants. For example, if the entire feed stream is discharged into the reaction medium via two feed holes that are azimuthally spaced from each other by 89 degrees, for purposes of determining the azimuth distribution in four azimuthal quadrants, 100 100 percent by weight of the feed stream is discharged into the reaction medium in an azimuthal quadrant only because the quadrants azimuths can be oriented azimutially such that both of the feed holes are located in an azimuthal quadrant only. In addition to the advantages associated with the appropriate azimuthal spacing of the feed holes, it has also been found that the proper radial spacing of the feed orifices in a bubble column reactor may also be important. It is preferred that a substantial portion of the oxidizable compound introduced into the reaction medium is discharged via feed holes that are radially spaced inward from the side wall of the container. Thus, in one embodiment of the present invention, a substantial portion of the oxidizable compound enters the reaction zone via the supply orifices located in a preferred radial "feeding zone" that is spaced inwardly from the straight sidewalls. that define the reaction zone. With reference again to FIG. 7, the preferred radial feed zone "FZ" can take the form of a theoretical straight cylinder centered in the reaction zone 28 and having an outside diameter (Do) of 0.9D, where "D" is the diameter of the zone of reaction 28. Thus, an external ring "OA" having a thickness of 0.05D is defined between the preferred radial feed zone FZ and the inside of the wall lateral defining the reaction zone 28. It is preferred that little or nothing of the oxidizable compound is introduced into the reaction zone 28 via the feed holes located in this eternal OA ring. In another embodiment, it is preferred that little or nothing of the oxidizable compound be introduced into the center of the reaction zone 28. Thus, as illustrated in FIG. 8, the preferred radial feed zone FZ can take the form of a theoretical straight ring centered in the reaction zone 28, which has an external diameter Do of 0.9D, and which has an internal diameter Di of 0.2D. Thus, in this embodiment, an inner cylinder having a diameter of 0.2D is "cut" from the center of the preferred radial feed zone FZ. It is preferred that little or nothing of the oxidizable compound is introduced into the reaction zone 28 via the feed orifices located in this internal cylinder IC. In a preferred embodiment of the present invention, a substantial portion of the oxidizable compound is introduced into the reaction medium 36 via the feed holes located in the preferred radial feed zone, regardless of whether the preferred radial feed zone has the cylindrical or annular shape described in the above. More preferably, in at least about 25 percent of the oxidizable compound is discharged into the reaction medium 36 via the feeding holes located in the preferred radial feeding zone. Still more preferably, at least about 50% by weight of the oxidizable compound is discharged into the reaction medium 36 via the feed holes located in the preferred radial feed zone. Much more preferably, at least 75 weight percent of the oxidizable compound is discharged into the reaction medium 36 via the feed holes located in the preferred radial feed zone. Although the theoretical azimuthal quadrants and the theoretical preferred radial feed zone in FIGS. 7 and 8 are described with reference to the distribution of the liquid phase feed stream, it has been found that the appropriate azimuthal and radial distribution of the oxidant stream distribution in gas phase can also provide certain advantages. Thus, in one embodiment of the present invention, the description of the azimuthal and radial distribution of the liquid phase feed stream, provided in the foregoing, also applies in the manner in which the oxidant stream in gas phase is introduced. in the reaction medium 36. Referring now to FIGS. 12-15, an alternative oxidant spray tube 200 is illustrated as generally comprising a ring member 202 and a pair of oxidant inlet passages 204, 206. The oxidant spray tube 200 of FIGS. 13-15 is similar to the oxidant sprayer tube 34 of FIGS. 1-11 with the following three primary differences: (1) the oxidizing spray tube 200 does not include a diagonal cross member; (2) the upper portion of the ring member 202 has no orifices to discharge the oxidant in an upward direction; Y (3) the oxidant spray tube 2002 has much more holes in the lower portion of the ring member 202. As best illustrated in FIGS. 14 and 15, the bottom portion of the oxidant spray tube ring 202 has a plurality of oxidant ports 208. The oxidant ports 208 are preferably configured such that at least about 1 percent of the total open area defined by the holes Oxidant 208 is located down the centerline 210 (FIG.15) of the ring member 202, where the center line 210 is located at the elevation of the volumetric centroid of the ring member 202. More preferably, at least about 5 times 100 percent of the total open area defined by all the oxidant orifices 208 are located down the center line 210 with at least about 2 percent of the total open area that is defined by the orifices 208 that discharge the oxidant stream in one direction generally downward within about 30 degrees of vertical still more preferably, at least about 20 percent of the total open area defined by all the oxidant orifices 208 is located down from the center line 210, with at least about 10 percent of the total open area which is defined by the orifices 208 which discharge the oxidant stream in a generally downward direction within 30 degrees of the vertical. Much more preferably, at least about 75 percent of the total open area defined by all oxidant orifices 208 is located below the centerline 210, with at least about 40 percent of the total open area defined by the holes 208 that discharge the oxidant stream in a generally downward direction within 30 degrees of the vertical. The fraction of the total open area defined by all of the oxidant orifices 208 that are located above the center line 210 is preferably less than about 75 percent, more preferably less than about 50 percent, still more preferably less than about 25 percent , and much more preferably less than 5 percent. As illustrated in FIGS. 14 and 15, the oxidant ports 208 include the downward orifices 208a and the oblique holes 208b. The downward holes 208a are they configure to discharge the oxidant stream generally downwards at an angle within about 30 degrees of vertical, more preferably within about 15 degrees of vertical, and much more preferably within 5 degrees of vertical. The oblique holes 208b are configured to discharge the oxidant stream generally outward and downward at an angle "A" that is in the range of about 1 to about 75 degrees from vertical, more preferably angle A is in the range of about 30 to approximately 60 degrees from vertical, and much more preferably angle A is in the range of approximately 40 to 50 degrees vertical. It is preferred that substantially all oxidant holes 208 have approximately the same diameter. The diameter of the oxidant orifices 208 is preferably in the range of about 2 to about 300 millimeters, more preferably in the range of about 4 to about 120 millimeters, and most preferably in the range of 8 to 60 millimeters. The total number of oxidant orifices 208 in the ring member 202 is selected to meet the low pressure drop criteria detailed below. Preferably, the total number of oxidant orifices 208 formed in the ring member 202 is at least about 10, more preferably the total number of oxidant orifices 208 is in the range of about 20 to about 200, and most preferably the total number of oxidant orifices 208 is in the range of 40 to 100. Although FIGS. 12-15 illustrate a very specific configuration for oxidant sprayer tube 200, it is now mentioned that a variety of oxidant sprayer tube configurations can be employed to achieve the advantages described herein. For example, the oxidant spray tube does not necessarily need to have the octagonal ring member configuration illustrated in FIGS. 12-13. Rather, it is possible for the oxidant spray tube to be formed of any configuration of flow conduit (s) that employs a plurality of spaced holes to discharge the oxidant stream. The size, number, and direction of discharge of the oxidant orifices in the flow conduit are preferably within the ranges set forth above. In addition, the oxidant spray tube is preferably configured to provide the azimuthal and radial distribution of the molecular oxygen described above. Without considering the specific configuration of the oxidant spray tube it is preferred that the oxidant spray tube be physically configured and operated in a Manea Minimize the pressure drop associated with the discharge of the oxidant stream out of the flow conduit (s), through the oxidant orifices, and into the reaction zone. Such a pressure drop is calculated as the time-averaged static pressure of the oxidant stream within the flow conduit at oxidant inlets 66a, b, c, d of the oxidant spray tube minus the time-averaged static pressure in the zone of reaction at the elevation where one half of the oxidant stream is introduced above the vertical location and one half of the oxidant stream is introduced below the vertical location. In a preferred embodiment of the present invention, the time-averaged pressure drop associated with the discharge of the oxidant stream from the oxidant spray tube is less than about 0.3 megapascal (MPa), more preferably less than about 0.2 MPa, still more preferable less than about 0.1 MPa, and much more preferably less than 0.05 MPa. Under the preferred operating conditions of the bubble column reactor described herein, the pressure of the oxidant stream within the flow conduit (s) of the oxidant spray tube is preferably in the range of about 0.35 to about 1 MPa, more preferably in the range of about 0.45 to about 0.85 MPa, and most preferably in the range from 0.5 to 0.7 MPa. As alluded to in the foregoing with reference to the configuration of the oxidant spray tube illustrated in FIGS. 2-5, it may be desirable to continuously or periodically wash the oxidant spray tube with a liquid (eg, acetic acid, water, and / or para-xylene) to prevent fouling of the oxidant spray tube with solids. When such washing with liquid is employed, it is preferred for an effective amount of the liquid (i.e., not only the smaller amount of liquid droplets that could naturally be present in the oxidant stream to be passed through the oxidant spray tube and outside). of the oxidant orifices for at least a period of more than one minute each day.When a liquid is discharged continuously or periodically from the oxidant spraying tube, it is preferred that the ratio of the mass flow rate of the liquid through the tube oxidizer sprayer at the expense of mass flow of molecular oxygen through the oxidant spray tube is in the range of from about 0.05: 1 to about 30: 1, or in the range from about 0.1: 1 to about 2: 1, or even in the range of 0.2: 1 to 1: 1. In one embodiment of the present invention, a significant portion of the oxidizable compound (eg, para-xylene) can be introduced into the reagent zone. action a through the oxidant spray tube. In such a configuration, it is preferred that the oxidizable compound and molecular oxygen be discharged from the oxidant spray tube through the same orifices in the oxidant spray tube. As mentioned in the above, the oxidizable compound is typically a liquid in STP. Therefore, in this embodiment, a two-phase stream can be discharged from the oxidant spray tube, with the liquid phase comprising the oxidizable compound and the gas phase comprising the molecular oxygen. It should be recognized, however, that at least a portion of the oxidizable compound may be in a gaseous state when discharged from the oxidant spray tube. In one embodiment, the liquid phase discharged from the oxidant spray tube is formed predominantly of the oxidizable compound. In another embodiment, the liquid phase discharged from the oxidant spray tube has substantially the same composition as the feed stream, described above. When the liquid phase discharged from the oxidant spray tube has substantially the same composition as the feed stream, such a liquid phase can comprise a solvent and / or a catalyst system in the amounts and ratios described above with reference to the composition of the feeding current. In one embodiment of the present invention, it is preferred that at least about 10 weight percent for all the oxidizable compound introduced in the reaction zone be introduced via the oxidant spray tube, more preferably at least about 40 weight percent of the oxidizable compound is introduced into the the reaction zone via the oxidant sprayer tube, and most preferably at least 80 weight percent of the oxidizable compound is introduced into the reaction zone via the oxidant sprayer tube. When all or part of the oxidizable compound is introduced into the reaction zone via the oxidizing spray tube, it is preferred that at least about 10 weight percent of all the molecular oxygen introduced into the reaction zone has been introduced by the Via the same oxidant sprayer tube, more preferably at least about 40 weight percent of the oxidizable compound is introduced into the reaction zone via the same oxidant sprayer tube, and most preferably at least 80 percent by weight. The weight of the oxidizable compound is introduced into the reaction zone via the same oxidant spray tube. When a significant portion of the oxidizable compound is introduced into the reaction zone via the oxidant spray tube, it is preferred that one or more temperature sensing devices (eg, thermocouples) be placed in the oxidant spray tube. These temperature sensors are They can be used to help ensure that the temperature in the oxidant spray tube does not become dangerously high. With reference now to FIGS. 16-18, the bubble column reactor 20 is illustrated as including an internal deaeration vessel 300 placed at the bottom of the reaction zone 28 near the suspension outlet 38. It has been discovered that the secondary reactions which form impurities occur in a relatively high proportion during the deaeration of the reaction medium 36. As used herein, "deaeration" will indicate the decoupling of a gas phase from the multi-phase reaction medium. When the reaction medium 36 is highly aerated (> 0.3 gas containment), the formation of impurities is minimal. When the reaction medium 36 is highly deaerated (> 0.01 gas containment), the formation of impurities is also minimal. However, when the reaction medium is partially aerated (0.01.0.3 gas containment), the undesirable side reactions are promoted and increased and the impurities are generated. The deaeration vessel 300 addresses these and other problems by minimizing the volume of the reaction medium 36 in a partially aerated state, and by minimizing the time it takes to deaerate the reaction medium 36. A substantially deaerated suspension is produced from the bottom of the deaeration vessel 300 if it leaves reactor 20 via suspension outlet 38. The substantially deaerated suspension preferably contains less than about 5 volume percent gas phase, more preferably less than about 2 volume percent phase of gas, and much more preferably less than 1 percent by volume of gas phase. In FIG. 16, the bubble column reactor 20 is illustrated as including a level controller 302 and a flow control valve 304. The level controller 302 and the flow control valve 304 cooperate to maintain the reaction medium 36 in a substantially constant rise in the reaction zone 28. The level controller 302 is operable to detect (e.g., detecting the differential pressure level or detecting the nuclear level) the elevation of the upper surface 44 of the reaction medium. and generating a control signal 306 responsive to the raising of the reaction medium 36. The flow control valve 304 receives the control signal 306 and adjusts the flow rate of a suspension through a suspension outlet conduit 308. Thus, the flow rate of the suspension outside the suspension outlet 38 may vary between a maximum suspension volumetric flow rate (Fma?) When the elevation of the reaction medium. 6 is very high and a minimum flow volumetric suspension expense (Fmax) when the Elevation of the reaction medium 36 is very low. In order to remove the solid phase oxidation product from the reaction zone 28, a portion must first be passed through the deaeration vessel 300. The deaeration vessel 300 provides an internal volume of low turbulence which allows the gas of the reaction medium 36 to rise naturally out of the liquid and solid phase of the reaction medium 36 as the flow of liquid and solids down towards the suspension outlet 38. The rise of the gas phase outside the liquid phases and solid is caused by the natural upward flotation of the gas phase in the liquid and solid phases. When the deaeration vessel 300 is employed, the transition from the reaction medium 36 from a three phase medium, fully aerated to a two phase suspension, completely deaerated is fast and efficient. With reference now to FIGS. 17 and 18, deaeration vessel 300 includes a generally straight side wall 308 that defines a deaeration zone 312 therebetween. Preferably, the side wall 308 extends upwardly within about 300 degrees of the vertical, more preferably within about 10 degrees of vertical. Much more preferably, the side wall 308 is substantially vertical. The deaeration zone 312 is separated from the reaction zone 28 and has height "h" and a diameter "d". An upper end 310 of the side wall 308 is opened to receive the reaction medium from the reaction zone 28 in the internal volume 312. The lower end of the side wall 308 is fluidly coupled to the suspension outlet 38 by way of a transition 314. In certain cases, such as when the opening of the suspension outlet 38 is large or when the diameter "d" of the side wall 308 is small, the transition section 314 can be eliminated. As perhaps better illustrated in FIG. 18, the deaeration vessel 300 may also include a vortex breaker 316 positioned in the deaeration zone 312. The vortex breaker 316 may be any structure operable to inhibit vortex formation as the solid and liquid phases flow downward toward the vortex. suspension outlet 38. In order to allow the coupled disengagement of the gas phase from the solid and liquid phases in the deaeration vessel 300, the height "h" and the horizontal cross-sectional area of the internal deaeration zone 312 They are carefully selected. The height "h" and the horizontal cross-sectional area of the internal deadening zone 312 must provide sufficient distance and time so that even when the maximum amount of suspension is being withdrawn (ie, when the suspension is being withdrawn in Fmax) ), substantially all of the volume of Gas bubbles can be lifted out of the solid and liquid phases before the gas bubbles reach the bottom outlet of the deaeration vessel 300. Thus, it is preferred that the cross-sectional area of the deaeration zone 312 be such that the maximum downward velocity (Vdmax) of the liquid and solid phases through the deaeration zone 312 is substantially less than the natural rate of rise (Vu) of the gas phase bubbles through the liquid and solid phases . The maximum downward velocity (Vdmax) of the liquid and solid phases through deaeration zone 312 occurs at the maximum suspension volume flow rate (Fmax) discussed in the foregoing. The velocity "of natural elevation (Vu) of the gas bubbles through the liquid and solid phases varies depending on the size of the bubbles, however, the natural elevation velocity (Vuo.s) of the diameter gas bubbles 0.5 centimeter through the liquid and solid phases can be used as a cut-off value because substantially all of the volume of bubbles initially in the reaction medium 36 will be larger than 0.5 centimeter Preferably, the cross-sectional area of The deaeration zone 312 is such that the Vdmax is less than about 75 percent Vu0.5 more preferably Vdmax is less than about 40 percent Vuo.s, much more preferably the VDmax is less than 20 percent Vu0. 5.

The downward velocity of the liquid and solid phases in the deaeration zone 312 of the deaeration vessel 300 is calculated as the volumetric flow rate of the deaerated suspension through the outlet of the suspension 38 divided by the minimum cross-sectional area of the deaeration zone 312. the downward velocity of the liquid and solid phases in the deaeration zone 312 of the deaeration vessel 300 is preferably less than about 50 centimeters per second, more preferably less than about 30 centimeters per second, and much more preferably less than 10 centimeters per second. Now it is noted that although the vertical side wall 308 of the deaeration vessel 300 is illustrated as having a cylindrical configuration, the side wall 308 could comprise a plurality of side walls forming a variety of configurations (eg, triangular, square, oval), while the walls define an internal volume that has an appropriate volume, cross-sectional area, width "d" and height "h". In a preferred embodiment of the present invention, "d" is in the range of about 0.2 to about 2 meters, more preferably in the range of about 0.3 to about 1.5 meters, and much more preferably in the range of 0.4 to 1.2 meters. In a preferred embodiment of the present invention, "h" is in the range of about 0.3 meters to about 5 meters, more preferably in the range of about 0.5 to about 3 meters, and much more preferably in the range of 0.75 to 2 meters. In a preferred embodiment of the present invention, the side wall 308 is substantially vertical so that the horizontal cross-sectional area of the deaeration zone 312 is substantially constant along the full height "h" of the deaeration zone 312 Preferably, the maximum horizontal cross-sectional area in the deaeration zone 312 is less than 25 percent of the maximum horizontal cross-sectional area of the reaction zone 28. More preferably, the maximum horizontal cross-sectional area of the area of deaeration 312 is in the range of from about 0.1 to about 10 percent of the maximum cross-sectional area of the reaction zone 28. Much more preferably, the maximum horizontal cross-sectional area of the deaeration zone 312 is in the range of 0.25. to 4 percent of the area of. maximum horizontal cross section of the reaction zone 28. Preferably, the maximum horizontal cross-sectional area of the deaeration zone 312 is in the range of about 0.02 to about 3 square meters, more preferably in the range of about 0.05 to about 2 square meters, and much more preferably in the range of 0.1 to 1.2 square meters. The volume of deaeration zone 312 is preferably less than about 5 percent of the total volume of reaction medium 36 or reaction zone 28. More preferably, the volume of deaeration zone 312 is in the range of about 0.01 to about 2 percent of the total volume of the reaction medium 36 or the reaction zone 28. Most preferably, the volume of the deaeration zone 312 is in the range of 0.05 to about 1 percent of the total volume of the reaction medium. or the reaction zone 28. The volume of deaeration zone 312 is preferably less than about 2 cubic meters, more preferably in the range of about 0.01 to about 1 cubic meter, and most preferably in the range of 0.05 to 0.5 meters cubic Returning now to FIG. 19, the bubble column reactor 20 are illustrated as it includes an external deaeration vessel 400. In this configuration, the aerated reaction medium 36 is removed from the reaction zone 28 via a raised orifice on the side of the reactor. the vessel shell 22. The removed aerated medium is transported to an external deaeration vessel 400 by way of a outer conduit 402 for the decoupling of the gas phase from the solid and liquid phases. The decoupled gas phase leaves deaeration vessel 400 via conduit 404, while the substantially deaerated suspension exits deaeration vessel 400 via conduit 406. In FIG. 19 the outlet conduit 402 is shown as being approximately straight, horizontal, and orthogonal to the container shell 22. This is merely a convenient configuration; and the outlet duct 402 may be otherwise in any aspect, to prove that it is usefully connected to the bubble column reactor 20 with the external deaeration vessel 400. Returning to the duct 404, it is useful for this duct to connect to or near the container of upper deaeration 400 in order to control a stagnant gas bag containing the oxidizable compound and the oxidant. In addition, conduits 402 and 404 may usefully comprise flow isolation means, such as valves. When the reaction medium 36 is removed from the reactor 20 via a high outlet, as shown in FIG. 19, it is preferred that the bubble column reactor 20 be equipped with a bottom outlet 408 near the bottom 53 of the reaction zone 28. The bottom outlet 408 and the bottom conduit 410, coupled thereto, can be used for the disinventation (ie, emptying of reactor 20 during suspensions. Preferably, one or more lower outlet 408 is provided at the bottom of a third of the height of the reaction medium 36, more preferably at the bottom of a quarter of the reaction medium 36, and most preferably at the lowest point of the reaction medium. reaction zone 28. With the removal of the elevated suspension and deaeration system shown in FIG. 19, the lower conduit 410 and the outlet 408 are not used to remove the suspension from the reaction zone 28 during oxidation. It is known in the art that solids tend to settle by gravity forces in non-aerated and otherwise unstirred portions of the suspension, including in stagnant flow conduits. In addition, settled solids (for example terephthalic acid) may tend to solidify in large agglomerates to continue precipitation and / or crystal reorganization. Thus, in order to avoid clogging of the lower flow conduit 410, a fraction of the deaerated suspension from the bottom of the deaeration vessel 400 can be used to continuously or intermittently wash the lower conduit 410 during the normal operation of the reactor 20. A medium The preferred way to provide such a suspension wash to line 410 is to periodically open a valve 412 in line 410 and leave a fraction of the deaerated suspension to flow through line 410 and into the reaction zone 28 via the inner orifice 408. Even though the valve 412 is completely or partially open, only a fraction of the slurry suspension flows through the lower conduit 410 and returns to the reaction zone 28. The remaining fraction of the deaerated suspension is not used to wash the lower conduit 410 is carried via the conduit 414 away from the reactor 20 for further downstream processing (eg, purification). During the normal operation of the bubble column reactor 20 over a substantial length of time (eg,> 100 hours), it is preferred that the amount of the deaerated suspension used to flood the lower conduit 410 is less than 50 percent in weight of the total deaerated suspension produced from the bottom of deaeration vessel 400, more preferably less than about 20 weight percent, and much more preferably less than 5 weight percent. Further, it is preferred that for a substantial length of time the average mass flow rate of the deaerated suspension used to flood the lower conduit 410 is less than about 4 times the average mass flow of the oxidizable compound in the reaction zone 28, more preferably less than about 2 times the average mass flux flow rate of the oxidizable compound in the reaction zone 28, still more preferably less than the average mass flow expense of the oxidizable compound in the reaction zone 28, and most preferably less than 0.5 times the average mass flow expense of the oxidizable compound in the reaction zone 28. With reference again to FIG. 19, deaeration vessel 400 includes a preferably cylindrical, substantially vertical side wall 416 that defines a deaeration zone 418. The deaeration zone 418 has a diameter "d" and a height "h". The height "h" is measured as the vertical distance between the location where the aerated reaction medium enters the deaeration vessel 400 and the bottom of the side wall 416. The height "h", the diameter "d", area, and the volume of deaeration zone 418 is preferably substantially the same as described above with reference to deaeration zone 312 of deaeration vessel 300 illustrated in FIGS. 16.18. In addition, the deaeration vessel 400 includes an upper section 420 formed by the extension of the side wall 416 above the deaeration zone 418. The upper section 420 of the deaeration vessel 400 can be of any height, although preferably it extends upwards. ao above the level of the reaction medium 36 in the reaction zone 28. The upper section 420 ensures that the gas phase takes place to disengage suitably of the liquid and solid phases before leaving the deaeration vessel 400 via conduit 404. It is now noted that although the conduit 404 is illustrated as it returns to the gas phase decoupled to the decoupling zone of the reactor 20, the conduit 404 could alternatively be coupled to vessel shell 22 at any elevation to outlet conduit 402. Optionally, conduit 404 could be coupled to gas outlet conduit 40 so that the uncoupled gas phase of deaeration vessel 400 is It combines with the steam stream from the top of the duct 40 and is sent downstream for further processing. Returning now to FIG. 20, the bubble column reactor 20 is illustrated as including a hybrid internal-external deaeration vessel 500. In this configuration, a portion of the reaction medium 35 is removed from the reaction zone 28 through a relatively high orifice. large 502 on the side wall of the container shell 22. The withdrawn reaction medium 36 is then transported through a relatively large diameter elbow conduit 504 and enters the upper portion of the deaeration vessel 500. In FIG. 20, the elbow conduit 504 is shown as it is connected orthogonally to the side wall of the container shell 22 as it comprises a soft crow through an angle of about 90 lll degrees. This is merely a convenient configuration; and the elbow conduit 504 may be otherwise in any aspect, provided that is usefully connected to the bubble column reactor 20 with the external deaeration vessel 500, as described. In addition, the elbow conduit 504 can usefully comprise flow isolation means, such as valves. In deaeration vessel 500, the gas phase moves upward, while the solid and liquid phases move downward. The upwardly moving gas phase can reenter the elbow conduit 504 and then escape through the orifice 502 back into the reaction zone 28. Thus, a countercurrent flow of the incoming reaction medium 36 and the existing decoupled gas can occur in port 502. The deaerated suspension exits deaeration vessel 500 via conduit 506. Deactivation vessel 500 includes a substantially vertical, preferably cylindrical side wall 508 defining a deaeration zone 510. The deaeration zone 510 it has a height "H" and a diameter "d". It is preferred that the raised orifice 502 and the elbow conduit 504 have a diameter the same as, or greater than, the diameter "d" or the deaeration zone 510. The height "h", the diameter "d" the area and the volume of deaeration zone 510 are preferably substantially the same as described in the foregoing with reference to the deaeration zone 312 of the deaeration vessel 300 illustrated in FIGS. 16-18. FIGS. 19 and 20 illustrate one embodiment of the bubble column reactor 20 where the solid product (e.g., crude terephthalic acid) produced in the reaction zone 28 is removed from the reaction zone 28 via a high outlet. Removal of the aerated reaction medium 36 from an elevated location above the bottom of the bubbling column reactor 20 can help to prevent the accumulation and stagnation of the poorly aerated reaction medium 36 at the bottom 52 of the reaction zone 28. According to other aspects of the present invention, the concentrations of oxygen and the oxidizable compound, for example para-xylene in the reaction medium 36 near the top of the reaction medium 36 are preferably lower than near the bottom. Thus, removal of the reaction medium 36 at a high location can increase the yield by decreasing the amount of the unreacted reactants removed from the reactor 20. Also, the temperature of the reaction medium 36 varies significantly in the vertical direction when the reactor Bubble column 20 is operated with the high STR and the gradients of the chemical composition as disclosed herein. Under such conditions, the temperature of the reaction medium 36 typically it will have minimal local wax from the lower end and the upper end of the reaction zone 28. Near the lower end, the minimum is related to the evaporation of the solvent near where all or part of the oxidant is admitted. Near the upper end, the minimum is again due to the evaporation of solvent, although here due to the pressure decline within the reaction medium. In addition, another local minimum may occur between the upper and lower ends where additional feed or oxidant is admitted to the reaction medium. Thus, there is one or more maximum temperature, driven by the exothermic heat of the oxidation reactions between the lower end and the upper end of the reaction zone 28. Removal of reaction medium 36 at a high temperature elevated location can be particularly advantageous with downstream processing that occurs at high temperatures, because the energy costs associated with heating the removed medium for downstream processing are reduced. Thus, in a preferred embodiment of the present invention and especially when the downstream processing occurs at higher temperatures, the reaction medium 36 is removed from the bubble column reactor 20 via a raised outlet (s) placed above the location (s) where at least 50 percent by weight of the stream of liquid phase feed and / or oxidant stream in gas phase enters the reaction zone 28. More preferably, the reaction medium 36 is removed from the bubbling column reactor 20 via a high output (s) placed above the location (s) where substantially all of the liquid phase feed stream and / or the gas phase oxidant stream enters the reaction zone 28. Preferably, at least 50 weight percent of the Solid phase and liquid phase components removed from the bubble column reactor 20 are removed via a high outlet (s). More preferably, substantially all of the solid phase and liquid phase components removed from the bubble column reactor 20 are removed via a high outlet (s). Preferably, the raised outlet (s) is located at least about ID above the lower end 52 of the reaction zone 28. More preferably, the raised outlet (s) is located at least about 2D above the lower end 52 of the reaction zone 28. Much more preferably, the raised outlet (s) is located at least 3D above the lower end 52 of the reaction zone 28. Given a height "h" of the reaction medium 36, it is preferred that the High output (s) is vertically located between about 0.2H and about 0.8H, more preferably between about 0.3H and about 0. 7H, and much more preferably between 0.4H and 0.6H. Further, it is preferred that the temperature of the reaction medium 36 at an elevated outlet of the reaction zone 28 be at least 1 ° C higher than the temperature of the reaction medium 36 at the lower end 52 of the reaction zone 28. More preferably, the temperature of the reaction medium 36 at the elevated outlet of the reaction zone 28 is in the range of about 1.5 to about 16 ° C hotter than the temperature of the reaction medium 36 at the lower end 52 of the zone 28. Much more preferably, the temperature of the reaction medium 36 at the elevated outlet of the reaction zone 28 is in the range of 2 to 12 ° C warmer than the temperature of the reaction medium 36 at the lower end 52 of the reaction zone 28. Referring now to FIG. 21, the bubble column reactor 20 is illustrated as including an alternative hybrid deaeration vessel 600 placed at the bottom of the reactor 20. In this configuration, the aerated reaction medium 36 is removed from the reaction zone 28 through a relatively large hole 602 at the lower end 52 of the container shell 22. The hole 602 defines the open upper end and the deaeration vessel 600. In the deaeration vessel 600, the gas phase moves upwards, while the phases solid and liquid move down. The gas phase moving upwards can reenter the reaction zone 28 through the orifice 602. Thus, a countercurrent flow of the incoming reaction medium and the existing decoupled gas can occur in the orifice 602. The deaired suspension leaves the deaeration vessel 600 via conduit 604. The deaeration vessel 600 includes a preferably cylindrical, substantially vertical side wall 606 defining a deaeration zone 608. The deaeration zone 608 has a height "h" and a diameter "d" " It is preferred that the orifice 602 have a diameter, or greater than, the diameter "d" of the reaction zone 608. The height "h", the diameter "d", the area and volume of the deaeration zone 608 are preferably substantially the same as described above with the de-aeration zone 312 of the deaeration vessel 300 illustrated in FIGS. 16-18. With reference now to FIG. 22, the bubble column reactor 20 of FIG. 21 is illustrated as including an alternative oxidant spray tube 620. The oxidant spray tube 620 includes a ring member 622 and a pair of inlet conduits 624, 626. The ring member 622 preferably has substantially the same configuration as the ring member 202, described in the foregoing with reference to FIGS 12-15. The conduits of 624, 626 inlet extended upwardly through the holes in the lower head 48 of the container shell 22 and provide the oxidant stream to the ring member 622. Referring now to FIG. 23, the bubble column reactor 20 of FIG. 21 is illustrated as it includes a means without a spray tube for introducing the oxidant stream into the reaction zone 28. In the configuration of FIG. 23, oxidant stream is provided to reactor 20 via oxidizing conduits 630, 632. Oxidant conduits 630, 632 are coupled to respective oxidant orifices 634, 636 in lower head 48 of vessel shell 22. The oxidant stream is introduced directly into the reaction zone 28 via oxidizer orifices 634, 536. Optional shock plates 638, 640 can be provided to divert the flow of oxidant stream once It has been entered micially into the reaction zone 28. As mentioned in the above, it is preferred that the oxidation reactor be configured and operated in a manner that avoids the high concentration zones of the oxidizable compound in the reaction medium because such areas can lead to the formation of impurities. One way to improve the initial dispersion of the oxidizable compound (by example para-xylene) in the reaction medium is by diluting the oxidizable compound with a liquid. The liquid used to dilute the oxidizable compound can originate from a portion of the reaction medium located at a substantial distance from the location (s) where the oxidizable compound is fed to the reaction zone. The liquid from a distant portion of the reaction medium can be circulated to the location near the entrance location of the oxidizable compound via the flow conduit that is placed internally and / or externally to the middle reaction vessel. FIGS. 24 and 25 illustrate two preferred methods of circulating liquid from a remote portion of the reaction medium to a location near the oxidizable compound entrance using an internal (FIG.24) or external (FIG.25) conduit. Preferably, the length of the flow conduit from its inlet (ie, orifice (s) where the liquid enters the conduit) at its outlet (ie, orifice (s) where the liquid is discharged from the conduit) is greater than about 1. meter, more preferably greater than about 3 meters, still more preferably greater than about 6 meters, and much more preferably greater than 9 meters. However, the actual length of the duct becomes less relevant if the fluid is obtained from a separate container, perhaps located immediately above or next to the container eh that the oxidizable feed is initially released. The liquid from any separate vessel containing at least some of the reaction medium is a preferred source for the initial dilution of the oxidizable compound. It is preferred that the liquid flows through the conduit, whatever the source, have a lower permanent concentration of the oxidizable compound than the reaction medium immediately adjacent to at least one inlet of the conduit. Further, it is preferred that the liquid flowing through the conduit have a concentration of oxidizable compound in the liquid phase below about 10,000 ppmw, more preferably below about 10,000 ppmw, still more preferably below about 1000 ppmw, and much more preferably below 100 ppmw, where the concentrations are measured before addition to the conduit of the increase of the oxidizable compound fed and of any separate, optional solvent feed. When it is measured after the addition of the oxidizable compound feed increase and the optional solvent feed it is preferable that the combined liquid stream entering the reaction medium has a concentration of oxidizable compound in the liquid phase below about 300,000 ppmw , more preferably below about 50,000 ppmw, and much more preferably below 10,000 ppmw. It is desirable to maintain the flow through the conduit in a sufficiently low ratio so that the circulated liquid does not suppress the desirable total gradient of the oxidizable compound within the reaction medium. In this regard, it is preferable that the ratio of the mass of the liquid phase in the reaction zone whereby the increase in the oxidizable compound is initially released at the mass flow rate of the liquid flowing through the conduit is greater than about 0.3 minutes more preferably greater than about one minute, still more preferably between about 2 minutes and about 120 minutes, and much more preferably between 3 minutes and 60 minutes. There are many means to force the liquid to flow through the conduit. Preferred means include gravity, eductors of all types employing gas or liquid, or both as the driving fluid, and mechanical pumps of all types. When an eductor is used, one embodiment of the invention uses an automotive fluid at least one fluid selected from the group consisting of: oxidizable compound feed (liquid or gas) oxidant feed (gas), solvent feed (liquid) and a pumped source of reaction medium (suspension). Another modality uses as a motor fluid at least two fluids selected from the group consisting of:oxidizable compound, oxidizer feed, and solvent feed. Yet another embodiment uses as a driving fluid a combination of oxidizable compound feed, oxidant feed, and solvent feed. The appropriate diameter or diameters of the circulation conduit may vary according to the quantity and properties of the material being carried, the energy available to force the flow movement, and considerations of capital costs. It is preferable that the minimum diameter for such a conduit be greater than about 0.02 meters, more preferably between about 0.06 meters, and about 2 meters, and much more preferably between 0.12 and 08 meters. As mentioned in the above, it is desirable to control the flow through the conduit at certain preferred intervals. There are many means known in the art to effect this control by adjusting an appropriate fixed geometry during the construction of the flow conduit. Another preferred embodiment is to use geometries that are variable during operation, notably including valves of all kinds and descriptions, including both manual operation and operation propelled by any means, including control spirals of rear feed of a detector element or without the . Another preferred means for controlling the flow of liquid from dilution is to vary the input energy between the inlet and outlet the conduit. The preferred means includes changing the flow rate of one or more fluids to an eductor, changing the energy input to a pump actuator, and changing the density difference or elevation difference when using gravitational force. These preferred means can also be used in all combinations. The conduit used for the circulation of the liquid of the reaction medium may be of any type known in the art. One embodiment employs a conduit constructed in whole or in part using conventional piping materials in whole or in part using the reaction vessel wall as a part of the conduit. A conduit can be built completely enclosed within the boundaries of the reaction vessel (FIG.24), or it can be completely built out of the reaction vessel (FIG.25), or it can comprise sections both inside and without the reaction vessel. The inventors contemplate that, particularly in larger reactors, it may be desirable to have multiple conduits and various designs for the movement of the liquid through the conduit. In addition, it may be desirable to provide multiple outputs in multiple positions on one or all of the conduits. Design particulars will balance the complete gradient desirable in the permanent concentrations of the oxidizable compound with the initial desirable dilution of the oxidizable compound feed according to other aspects of the current invention. FIGS. 24 and 25 both illustrate designs employing a deaeration vessel coupled to the conduit. This deaeration vessel ensures that the portion of the reaction medium used to dilute the incoming oxidizable compound is substantially deaerated suspension. It is now noted, however, that the liquid or suspension used to dilute the oxidizable incoming compound may be in an aerated form as well as a deaerated form. The use of a liquid flowing through a conduit to provide dilution of oxidizable compound feed is particularly useful in bubble column reactors. In addition, in the bubbling column reactors, a good benefit for the initial dilution of the feed of the oxidizable compound can be achieved even if the addition of the oxidizable compound feed directly into the conduit, providing that the outlet of the conduit is sufficiently close to the addition position of the oxidizable compound. In such an embodiment, it is preferable that the conduit outlet be located within approximately 27 conduit outlet diameters of the nearest addition location for the oxidizable compound, more preferably within approximately 9 diameters of duct outlet, still more preferably within about 3 duct outlet diameters, and most preferably within a duct outlet diameter. It has also been found that flow eductors may be useful for the initial dilution of the oxidizable compound feed in the oxidation bubbling columns according to one embodiment of the present invention, even without the use of conduits to obtain the liquid of dilution of a distant portion of the reaction medium. In such cases, the eductor is located within the reaction medium and has an open path of the reaction medium in the throat of the eductor, where the low pressure is removed in the adjacent medium. Examples of two possible eductor configurations are illustrated in FIGS. 26 and 27. In a preferred embodiment of these eductors, the closest location of the feed of the oxidizable compound is within about 4 meters, more preferably within about 1 meter and much more preferably 0.3 meters from the throat of the eductor. . In another embodiment, the oxidizable compound is fed under pressure as a driving fluid. In yet another embodiment, either the solvent or the oxidant is fed under pressure as an additional drive fluid together with the oxidizable compound. In still another embodiment, both the solvent and the oxidant are they feed under pressure as an additional drive fluid together with the oxidizable compound. The inventors contemplate that, particularly in larger reactors, it may be desirable to have multiple eductors and various designs located in various positions within the reaction medium. The design particulars will balance the desirable complete gradient in the permanent concentrations of the oxidizable compound with the desirable initial dilution of the oxidizable compound feed, according to other aspects of the current invention. In addition, the inventors contemplate that the outflow of bubbles from an eductor can be oriented in any direction. When multiple eductors are used, each eductor can be oriented separately, again in any direction. As mentioned in the foregoing, certain physical and operational characteristics of the bubble column reactor 20, described in the foregoing with reference to FIGS. 1-27, provide vertical gradients in the concentrations of pressure, temperature and reagent (ie, oxygen and oxidizable compound) of the reaction medium 36. As discussed above, these vertical gradients can provide a more effective oxidation process and economic as it is compared to conventional oxidation processes, which favor the medium of well-mixed reaction of relatively uniform pressure, temperature, and reagent concentration throughout. The vertical gradients for oxygen, the oxidizable compound (for example, para-xylene), and the temperature made possible by employing an oxidation system according to one embodiment of the present invention, will now be discussed in greater detail. With reference now to FIG. 28, in order to quantify the reagent concentration gradients leaving in the reaction medium 36 during oxidation in the bubble column reactor 20, the entire volume of the reaction medium 36 can theoretically be divided into 30 discrete horizontal slices of equal volume Fig. 28 illustrates the concept of dividing the reaction medium 36 into 30 discrete horizontal cuts of equal volume. With the exception of the highest and lowest horizontal cuts, each horizontal cut is a discrete volume linked at its top and bottom by imaginary horizontal planes and linked on its sides by the reactor wall 20. The highest horizontal cut is joined on its bottom by an imaginary horizontal plane and on its upper part by the upper surface of the reaction medium 36. The lower horizontal cut is joined on its upper part by an imaginary horizontal plane and on its bottom by the bottom of the shell of container. Once the means of reaction 36 has been theoretically divided into 30 discrete horizontal cuts of equal volume, the concentration averaged in time and averaged in volume of each horizontal cut can then be determined. The individual horizontal cut that has the maximum concentration of all 20 horizontal cuts can be identified as the "horizontal cut C-max". The individual horizontal section located above the horizontal section C-max and having the minimum concentration of all the horizontal sections located above the horizontal section C-max can be identified as the "horizontal section C-min. can be calculated as the ratio of the concentration in the horizontal section C-max to the concentration in the horizontal section C-min With respect to the quantification of the oxygen concentration gradient, when the reaction medium 36 is theoretically divided into 30 sections discrete horizontals of equal volume, a horizontal cut 02-max is identified since it has the maximum oxygen concentration of all 30 horizontal cuts and a horizontal cut 02-min is identified since it has the minimum oxygen concentration of the horizontal cuts located above the horizontal section 02-max The oxygen concentrations of the horizontal sections are measured in the ga s of the reaction medium 36 on a wet molar basis averaged over time and averaged in volume. It is preferred that the ratio of the oxygen concentration of the horizontal cut 02-max to the oxygen concentration of the horizontal cut 02-min be in the range of about 2: 1 to about 25: 1, more preferably in the range of about 3. : 1 approximately 15: 1, and much more preferably in the range of 4: 1 to 10: 1. Typically, the horizontal cut 02-max will be located near the bottom of the reaction medium 36, while the horizontal cut 02-min will be located near the top of the reaction medium 36. Preferably, the horizontal cut 02-min is one of 5 more superior horizontal cuts of the 30 discrete horizontal cuts. Much more preferably, the horizontal cut 02-min is one of the most superior of the 30 discrete horizontal cuts, as illustrated in FIG. 28. Preferably, the horizontal cut 02-max is one of the 10 lowest horizontal cuts of the 30 discrete horizontal cuts. Much more preferably, the horizontal cut 02-max is one of the lowest horizontal cuts of the 30 discrete horizontal cuts. For example, FIG. 28 illustrates the horizontal section 02-max as the third horizontal section of the reactor bottom 20. It is preferred that the vertical spacing between the horizontal sections 02-min and 02-max be at least approximately 2W, more preferably at least about 4W, and much more preferably at least 6W. It is preferred that the vertical spacing between the horizontal cuts 02-min and 02-max be at least about 0.2H more preferably at least about 0.4H, and much more preferably at least 0.6H. The oxygen concentration averaged over time and averaged over a wet basis of the 02-min cut is preferably in the range of about 0.1 to about 3 mole percent, more preferably in the range of about 0.3 about 2 percent in mol, and much more preferably in the range of 0.5 to 1.5 mol percent. The time-averaged and volume-averaged oxygen concentration of the horizontal cut 02-max is preferably in the range of about 4 to about 20 mole percent, more preferably in the range of about 5 to about 15 mole percent and much more preferably in the range of 6 to 12 mole percent. The time-averaged concentration of oxygen on a dry basis, in the gaseous effluent discharged from the reactor 20 via the gas outlet path 40 is preferably in the range of from about 0.5 to about 9 mole percent, more preferably in the range of about 1 to about 7 per one hundred mole, and much more preferably in the range of 1.5 to 5 mole percent. Because the concentration of oxygen deteriorates so markedly in the upper part of the reaction medium 36, it is desirable that the demand for oxygen be reduced in the upper part of the reaction medium 36. This reduced demand for oxygen near the upper part of the reaction medium 36 can be achieved by creating a vertical gradient in the concentration of the oxidizable compound (for example para-xylene), where the minimum concentration of the oxidizable compound is located near the top of the reaction medium 36. With With respect to the quantification of the oxidizable compound (for example, para-xylene), the concentration gradient, when the reaction medium 36 is theoretically divided into 30 discrete horizontal cuts of equal volume, a horizontal section OC-max is identified as having the maximum oxidizable compound concentration of all 30 horizontal cuts and a horizontal cut OC-min is identified since it has the concentration of minimum oxidizable compound of the horizontal cuts located above the horizontal section OC-max. The oxidizable compound concentrations of the horizontal cuts are measured in the liquid phase on a mass fraction basis averaged in time and averaged in volume. It is preferred for the relationship from the oxidizable compound concentration of the OC-max horizontal cut to the oxidizable compound concentration of the OC-min horizontal cut that is greater than about 5: 1, more preferably greater than about 10: 1, still more preferably greater than about 20: 1 and much more preferably in the range of 40: 1 to 1000: 1. Typically, the OC-max horizontal cut will be located near the bottom of the reaction medium 36, while the horizontal cut OC-min will be located near the top of the reaction medium 36. Preferably, the horizontal cut OC-min is one of the 5 most superior horizontal cuts of the 30 discrete horizontal cuts. Much more preferably, the OC-min horizontal cut is one of the most superior of the 30 full horizontal cuts, as illustrated in FIG- 28. Preferably, the OC-max horizontal cut is one of the 10 lowest horizontal cuts of the 30 discrete horizontal cuts. Much more preferably, the OC-max horizontal cut is one of the 5 lowest horizontal cuts of the 30 discrete horizontal cuts. For example, FIG. 28 illustrates the horizontal section OC-max as the fifth horizontal section of the bottom of the reactor 20. It is preferred that the vertical spacing between the horizontal sections OC-min and OC-max be at least approximately 2W, where "" is the width maximum of the reaction medium 36. More preferably, the Vertical spacing between the horizontal sections OC-min and OC-max is at least about 4W, and much more preferably at least 6W. Given a height "h" of the reaction medium 36, it is preferred that the vertical spacing between the horizontal sections OC-min and OC-max be at least about 0.2H, more preferably at least about 0.4H, and much more preferably at at least 0.6H. The concentration of time-averaged and volume-averaged oxidizable compound (for example, para-xylene) in the liquid phase of the horizontal cut OC-min is preferably less than about 5,000 ppmw, more preferably less than about 2,000 ppmw, still more preferably lower than about 400 ppmw, and much more preferably in the range of 1 ppmw to 100 ppmw. The concentration of time-averaged and volume-averaged oxidizable compound in the liquid phase of the OC-max horizontal cut is preferably in the range of about 100 ppmw to about 10,000 ppmw, more preferably in the range of about 200 ppmw to about 5,000 ppmw and much more preferably in the range of 500 ppmw to 3,000 ppmw. Although it is preferred that the bubble column reactor provide vertical gradients in the concentration of the oxidizable compound, it is also preferred that the volume percent of the reaction medium 36 has a concentration of oxidizable compound in the liquid phase above 1,000 ppmw is minimized. Preferably, the volume averaged volume percent of the reaction medium 36 has a concentration of oxidizable compound in the liquid phase above 1,000 ppmw is less than about 9 percent, more preferably less than about 6 percent and much more preferably lower that 3 percent. Preferably, the volume averaged volume percent of the reaction medium 36 having a concentration of oxidizable compound in the liquid phase above 2,500 ppmw is less than about 1.5 percent, more preferably less than about 1 percent, and much more preferably less than 0.5 percent. Preferably, the volume percent averaged in time of the reaction medium having a concentration of the oxidizable compound in the liquid phase above 10,000 ppmw is less than about 0.3 percent, more preferably less than about 0.1 percent, and much more preferably less than 0.03 percent. Preferably, the volume averaged volume percent of the reaction medium 36 having a concentration of the oxidizable compound in the liquid phase above 25,000 ppmw is less than about 0.03 percent, more preferably less than about 0.015 percent, and much more less than 0.07 percent. The inventors note that the volume of the reaction medium 36 having high levels of the oxidizable compound need not be in a contiguous volume alone. In many cases, the chaotic flow patterns in a bubble column reaction vessel simultaneously produce two or more segregated but continuous portions of the reaction medium 36 having high levels of the oxidizable compound. At each time used in the average time, all segregated but continuous volumes larger than 0.0001 volume percent of the total reaction medium are added together to determine the total volume having the high levels of the oxidizable compound concentration in the liquid phase. In addition to the gradients of oxygen concentration and the oxidizable compound as discussed above, it is preferred that a temperature gradient exist in the reaction medium 36. Referring again to FIG. 28, this temperature gradient can be quantified in a manner similar to the concentration gradients by the theoretically divided reaction medium 36 in 30 discrete horizontal cuts of equal volume and the measurement of the temperature averaged in time and averaged in each cut volume . The horizontal cut with the lowest temperature outside the 15 lower horizontal cuts can then be identified as the horizontal cut T-min, and the horizontal cut located above the horizontal cut T-min and having the maximum temperature of all cuts above the horizontal cut T-min can then be identified as the "horizontal cut T-max". It is preferred that the horizontal cutting temperature T-max be at least about 1 ° C higher than the horizontal cutting temperature T-min. More preferably the horizontal cutting temperature T-max is in the range of about 1.25 to about 12 ° C higher than the horizontal cutting temperature T-min. Much more preferably in the horizontal cutting temperature T-max is in the range of 2 to 8 ° C higher than the horizontal cutting temperature T-min. The horizontal cutting temperature T-max is preferably in the range of about 125 to about 200 ° C, more preferably in the range of about 140 to about 180 ° C, and most preferably in the range of 150 to 170 ° C. Typically, the horizontal cut T-max will be located near the center of the reaction medium 36, while the horizontal cut T-min will be located near the bottom of the reaction medium 36. Preferably, the horizontal cut T-min is one of the 10 lower horizontal cuts of the 15 lowest horizontal cuts. Much more preferably, the horizontal cut T-min is one of the 5 lowest horizontal cuts of the 15 horizontal cuts Lower. For example, FIG. 28 illustrates the horizontal cut T-min and the second horizontal cut of the bottom of the reactor 20. Preferably, the horizontal cut T-max is one of the 20 horizontal horizontal cuts of the 30 discrete horizontal cuts. Much more preferably, the horizontal cut T-min is one of the 14 horizontal horizontal cuts of the 30 discrete horizontal cuts. For example, FIG. 28 illustrates the horizontal cut t-max as the horizontal cut 20 of the bottom of reactor 20 (ie, one of the 10 middle horizontal cuts). It is preferred that the vertical spacing between the horizontal cuts T-min and T-max be at least about 2W, more preferably at least 4W, and much more preferably at least 6W. It is preferred that the vertical spacing between the horizontal cuts T-min and T-max be at least about 0.2H, more preferably at least about 0.4H, and much more preferably at least 0.6H. As discussed in the foregoing, when a vertical temperature gradient exists in the reaction medium 36, it may be advantageous to remove the reaction medium 36 at a high location where the temperature of the reaction medium is higher, especially when the product removed. it undergoes further downstream processing at higher temperatures. Thus, when the reaction medium 36 is removed from the reaction zone 28 via one or more high outputs, as illustrated in FIGS. 19 and 20, it is preferred that the outlet (s) be located close to the horizontal cut T-max. Preferably, the raised outlet is located within the horizontal cuts of the horizontal cut T-max, more preferably within 5 horizontal cuts of the horizontal cut T-max, and much more preferably within 2 horizontal cuts of the horizontal cut T-max. It is now noted that many of the inventive features described herein can be employed in multiple oxidation reactor systems - not just systems employing an oxidation reactor alone. In addition, certain inventive features described herein may be employed in mechanically agitated and / or stirred agitation reactors with flow - not just the stirred reactors with bubbles (ie, bubble column reactors). For example, the inventors have discovered certain advantages associated with the step formation / variant oxygen concentration and / or oxygen consumption ratio throughout the reaction medium. The advantages realized by the formation of stages of the concentration / consumption of oxygen in the reaction medium can be realized if the total volume of the reaction medium is contained in a single container, or in multiple containers. In addition, the advantages realized by the formation of stages of concentration / consumption of oxygen in the reaction medium can be made if the reaction vessel (s) is mechanically stirred, stirred with fluid and / or stirred with bubbles. One way to quantify the degree of step formation of the oxygen concentration and / or consumption ratio in the reaction medium is to compare two or more 20 percent continuous volumes other than the reaction medium. These 20 percent continuous volumes do not need to be defined by any particular form. However, each 20 percent continuous volume must be formed from a contiguous volume of the reaction medium (ie, each volume is "continuous"), and 20 percent continuous volumes should not be put on each other ( that is, the volumes are "different"). FIGS. 29-31 illustrate that these distinct 20 percent continuous volumes can be located in the same reactor (FIG 29) or in multiple reactors (FIGS 30 and 31). It is noted that the reactors illustrated in FIGS. 29 and 31 can be mechanically agitated reactors, stirred with flow, and / or stirred with bubbles. In one embodiment it is preferred that the reactors illustrated in FIGS. 29-31 are stirred reactors with bubbles (ie, bubble column reactors). With reference now to FIG. 29 the reactor 20 is illustrated as it contains a reaction medium 36. The medium of The reaction includes a first continuous ve of 20 percent different 37 and a second ve of 20% different 39. Referring now to FIG. 30 a multiple reactor system is illustrated as including a first reactor 720a and a second reactor 720b. The reactors 720a, b cooperatively contain a total ve of a reaction medium 736. The first reactor 720a contains a first portion of the reaction medium 736a, while the second reactor 720b contains a second portion of the reaction medium 736b. A first continuous ve of 20 percent different 737 of the reaction medium 736 is shown as defined within the first reactor 720a, while a second continuous ve of 20% different 739 of the reaction medium 736 is shown as it is defined inside the second reactor 720b. With reference now to FIG. 31, a multiple reactor system is illustrated as including a first reactor 820a, a second reactor 820b, and a third reactor 820c. Reactors 820a, b, c cooperatively contain a total ve of reactor medium 836. First reactor 820a contains a first portion of reaction medium 836a; the second reactor 820b contains a second portion of the reaction medium 836b; and a third reactor 820c contains a third portion of the reaction medium 836c. A first continuous ve of 20 percent different 837 from the reaction medium 836 is shown as defined within the first reactor 820a; a second 20 percent continuous ve 839 of the reaction medium 836 is shown as defined within the second reactor 820b; and a third distinct 20 percent continuous ve 841 of the reaction medium 836 is shown as defined within the third reactor 820c. The formation of stages of the availability of oxygen in the reaction medium can be quantified by referring to the continuous ve of 20% of the reaction medium it has and the most abundant mole fraction of oxygen in the gas phase and when referring the ve continuous 20 percent reaction medium that has the most decreased mole fraction of oxygen in the gas phase. In the gas phase of the 20 percent continuous ve other than the reaction medium containing the highest concentration of oxygen in the gas phase, the oxygen concentration averaged over time and averaged over a wet basis is preferably in the range of about 3 to about 18 mole percent, more preferably in the range of about 3.5 to about 14 mole percent, and most preferably in the range of 4 to 10 mole percent. In the gas phase of the 20 percent continuous ve other than the reaction medium containing the lowest concentration of oxygen in the gas phase, the oxygen concentration averaged over time and ve averaged, on a wet basis, is preferably in the range of about 0.3 to about 5 mole percent, more preferably in the range of more preferably in the range of about 3.5 to about 14 mole percent, and much more preferably in the range of 4 to 10 percent mol. 0.6 to more preferably in the range of about 3.5 to about 14 mole percent, and much more preferably in the range of 4 to 10 mole percent, 4 mole percent, and much more preferably in the 0.9 range at 3 percent mol. In addition, the ratio in oxygen concentration averaged over time and averaged in ve, on a wet basis, in the continuous ve of 20 percent more abundant reaction medium compared to the continuous ve of 20 percent more decreased reaction medium it is preferably in the range of about 1.5: 1 to about 20: 1, more preferably in the range of about 2: 1 to about 12: 1, and most preferably in the range of 3: 1 to 9: 1. The formation of stages of the oxygen consumption ratio in the reaction medium can be quantified in terms of an oxygen-STR, initially described in the above. Oxygen-STR is previously described in the global sense (that is, from the perspective of oxygen- Average STR of the complete reaction medium); however, STR-oxygen can also be considered in a local sense (i.e., a portion of the reaction medium) in order to quantify the step formation of the oxygen consumption ratio throughout the reaction medium. The inventors have discovered that it is very useful to cause the oxygen-STR to vary throughout the reaction medium in general harmony with the desirable gradients reported in the present which relate to the pressure in the reaction medium and the mole fraction of the oxygen molecular weight in the gas phase of the reaction medium. Thus, it is preferable that the oxygen-STR reaction of a first continuous volume of 20 percent other than the reaction medium compared to the oxygen-STR of a second continuous volume of 20 percent other than the reaction medium is in the range of about 1.5: 1 about 20: 1, more preferably in the range of about 2: 1 to about 12: 1, and most preferably in the range of 3: 1 to 9: 1. In one embodiment the "first distinct 20-percent volume" is located closer than the "second 20-percent continuous volume" to the location where the molecular oxygen is initially introduced into the reaction medium. These large gradients in oxygen-STR are desirable if the partial oxidation reaction medium is contained in a reactor. bubbling column oxidation or in any type of reaction vessel in which the gradients are created at the pressure and / or mole fraction of the molecular oxygen in the gas phase of the reaction medium (for example, in a stirred vessel mechanically having vertically placed, multiple agitation zones achieved by using multiple impellers having strong radial flow, possibly increased by generally horizontal deviator assemblies, with the flow of oxidant rising generally upward from a feed near the lower portion of the container of reaction, although considerable further mixing of the oxidant flow may occur within each vertically placed agitation zone and that some further mixing of oxidant flow may occur between vertically adjacent agitation zones). That is, when a gradient exists in the pressure and / or mole fraction of the molecular oxygen in the gas phase in the reaction medium, the inventors have discovered that it is desirable to create a similar gradient in the chemical demand to dissolve the oxygen by the medium disclosed herein. A preferred means of causing the local oxygen-STR to vary is by controlling the feed locations of the oxidizable compound and by controlling the mixing of the liquid phase of the reaction medium to control the gradients. in the concentration of the oxidizable compound according to other descriptions of the present invention. Other useful means to cause the local oxygen-STR to vary include the causative variation in activity-reaction by causing local temperature variation and by changing the local mixture of the catalyst and solvent components (for example, by introducing an additional gas). to cause evaporative cooling in a particular portion of the reaction medium and by adding a stream of solvent containing a higher amount of water to decrease the activity in the particular portion of the reaction medium). As discussed in the foregoing with reference to FIGS. 30 and 31, the partial oxidation reaction can be usefully conducted in multiple reaction vessels wherein at least a portion, preferably at least 25 percent, more preferably at least 50 percent, and much more preferably at least 75 percent of the molecular oxygen leaving a first reaction vessel is conducted to one or more subsequent reaction vessels for consumption of a further increase, preferably more than 10 percent, more preferably 20 percent, and much more preferably more than 40 percent of the molecular oxygen leaving the first upstream reaction vessel. When the use of such serial flow of molecular oxygen from one reactor to another, it is desirable that the first reaction vessel is operated within a higher reaction intensity than at least one of the subsequent reaction vessels, preferably with the ratio of the vessel-average-oxygen-STR within the first reaction vessel to the vessel-average -US-STR within the subsequent reaction vessel in the range of about 1.5: 1 to about 20: 1, more preferably in the range of about 2: 1 to about 12: 1, and most preferably in the range of 3: 1 to 9: 1. As discussed in the foregoing, all types of the first reaction vessel (eg, bubble column, mechanically stirred, subsequent mixing, internally of stage, piston-type expense, and so on) and all types of reaction vessels Subsequent, which may or may not be of a different type than the first reaction vessel, are useful for the serial flow of molecular oxygen to subsequent reaction vessels according to the present invention. The means to cause the container-average-oxygen-STR to decline within the subsequent reaction vessels usefully include reduced temperature reduced concentrations of oxidizable compound, and reduced reaction activity of the particular mixture of the catalyst components and solvent (e.g. reduced cobalt, increased concentration of water, and addition of a catalytic retardant such as small amounts of ionic copper). In the flow of the first reaction vessel to a subsequent reaction vessel, the oxidant stream can be treated by any means known in the art such as compression or pressure reduction, heating cooling, and mass removal or mass addition of any amount or any type. However, the use to decline the container, average-oxygen-STR in the subsequent reaction vessels is particularly useful when the absolute pressure in the upper portion of the first reaction vessel is less than about 2.0 megapascal, more preferably less than about 1.6 megapascal, and much more preferably less than 1.2 megapascal. In addition, the use of the vessel-average-oxygen-STR decline in subsequent reaction vessels is particularly useful when the ratio of the absolute pressure in the upper portion of the first reaction vessel compared to the absolute pressure in the upper portion of minus one subsequent reaction vessel is in the range of about 0.5: 1 to 6: 1, more preferably in the range of 0.6: 1 to about 4: 1, and much more preferably in a range of 0.7: 1 to 2: 1 . The pressure reductions in the Subsequent vessels below these lower junctions excessively reduce the ability of molecular oxygen, and the pressure is increased above these higher bonds are increased costly compared to using a fresh supply of oxidant. When the use of serial flow of molecular oxygen to subsequent reaction vessels that have declining oxygen-average-vessel-STR, fresh feed streams of oxidizable compound, solvent and oxidant can flow into subsequent reaction vessels and / or in the first reaction vessel. The fluxes of the liquid phase and the solid phase, if present, of the reaction medium can flow in any direction between the reaction vessels. All or part of the gas phase leaving the first reaction vessel and entering a subsequent reaction vessel may flow separated from or mixed with portions of the liquid phase or the solid phase, if present, from the reaction medium of the first reaction vessel. A flow of the product stream comprising the liquid phase and the solid phase, if present, can be removed from the reaction medium in any reaction vessel in the system. With reference again to FIGS. 1-29, in one embodiment of the present invention, the oxidation bubbling column reactor 20 has a production ratio significantly higher than conventional oxidation bubble column reactors, particularly conventional bubble column reactors used to produce terephthalic acid. In order to produce increased production ratios, the size of the bubble column reactor 20 must be increased. However, the multi-phase, naturally convective fluid flow dynamics of the reaction medium in such a rising bubble column reactor is significantly, differently than the flow dynamics in smaller conventional reactors. It has been found that certain design and operating parameters are important for the proper functionality of upstream oxidation bubbling column reactors of high production ratio. When the bubbling column 20 is a rising oxidation bubbling column reactor of high production rate according to one embodiment of the present invention, the height "H" of the reaction medium 36 is preferably at least about 30 meters, more preferably in the range of about 35 to about 70 meters, and much more preferably in the range of 40 to 60 meters. The density and height of the reaction medium 36 in the rising bubble column reactor 20 causes a significant pressure differential. between the top of the reaction medium 36 and the bottom of the reaction medium 36. Preferably the pressure differential between the top and the bottom of the reaction medium 36 is at least about 1 bar, more preferably at least about 1.4 bar, and much more preferably in the range of 1.6 to 3 bar. The maximum width "W" of the reaction medium 36 is preferably at least about 2.5 meters, more preferably in the range of about 3 to about 20 meters, still more preferably in the range of about 3.25 to about 12 meters, and much more preferably in the range of 4 to 10 meters. The H: W ratio of the reaction medium 36 is preferably at least about 6: 1, more preferably in the range of about 8: 1 to about 20: 1, and most preferably in the range of 9: 1 to 15: 1. The total volume of the reaction medium 36 and / or the reaction zone 28 is preferably at least about 250 cubic meters, more preferably at least about 500 cubic meters and most preferably at least 100 cubic meters. During the operation of the bubbling column reactor of scale oxidation column 20, it is preferred that the time-averaged surface velocity of the gas phase of the reaction medium 36 in a quarter of a height, the half height, and / or three quarters of height is in the range of about 0.8 to about 5 meters per second, more preferably in the range of about 0.9 to about 3 meters per second, and much more preferably in the range of 1 to 2 meters per second. When the increased scale oxidation bubble column reactor 20 is used to produce terephthalic acid via the partial oxidation of para-xylene, it is preferred that the para-xylene be fed to the reaction zone 28 in a proportion of at least about 11,000 kilograms per hour, more preferably in a ratio in the range of about 20,000 to about 100,000 kilograms per hour, and most preferably in the range of 30,000 to 80,000 kilograms per hour. The. The terephthalic acid production ratio of the increased scale bubbling column 20 is preferably at least about 400 tons per day, more preferably at least about 700 tons per day, and most preferably in the range of 750 to 3,000 tons per day. day. Other design and operation parameters of the enlarged scale oxidation bubble column reactor 20 may be substantially the same as described initially in the foregoing with reference to FIGS. 1-29. It has been discovered that the variation of the area of Horizontal cross section of the reaction zone of a bubble column reactor along the height of the reactor can help to improve the fluid flow dynamics of the reaction medium especially in the oxidation bubble column reactor designs of increased scale discussed in the above. With reference now to FIG. 32, in one embodiment of the present invention, the container shell 22 of the oxidation bubble column reactor 20 includes a broad lower section 23, a narrow upper section 25, and a transition section 27. Preferably the upper and lower sections 23, 25 are substantially cylindrical in shape and are aligned along a common central upper axis. The transition section 27 can have any of the suitable shapes (for example a horizontal flat shape, an elliptical shape of 2.1, a hemispherical shape, and so on). Preferably, the transition section 27 is generally a generally frustroconical member which transitions the container shell 22 from the interior section of the broad lower section 23 to the narrow upper section 25. The lower section 23 of the container shell 22 defines an area of the lower wide reaction 29. The upper section 25 of the container shell 22 defines a narrow upper reaction zone 31. The transition section 27 defines a transition zone located between the reaction zones. lower and upper 29-31. The reaction zone 20, the lower reaction zone 29, the upper reaction zone 31, and the transition zone cooperatively form the total reaction zone of the oxidation bubbling column reactor 20 which receives the multi-phase reaction medium 36. In a preferred embodiment of the present invention, the maximum horizontal cross-sectional area of the reaction medium 36 in the lower reaction zone 29 is at least about 10 percent greater than the minimum cross-sectional area of the reaction medium. 36 in the upper zone 31. More preferably, the maximum cross-sectional area of the reaction medium 36 in the lower reaction zone 29 is in the range of about 25 to about 200 percent greater than the minimum cross-sectional area of the medium of reaction 36 in the upper reaction zone 31. Much more preferably, the maximum horizontal cross-sectional area of the medium Reaction zone 36 in the reaction zone 29 is in the range of about 35 to 160 percent greater than the minimum horizontal cross-sectional area of the reaction medium 36 in the upper reaction zone 31. As illustrated in FIG. 32 ', the lower reaction zone 29 has a maximum diameter "Di" that is greater than the minimum diameter "Du" of the upper reaction zone 31.

Preferably, the Di is at least about 5 percent greater than the Du. More preferably, the Di is in the range of about 10 to about 100 percent greater than about Du. Much more preferably, Di is in the range of 15 to 50 percent greater than Du. FIG. 32 also illustrates that the lower reaction zone 29 has a maximum height "Li", the upper reaction zone 31 has a maximum height "Lu", and the transition zone has a maximum height "Lt". It should be noted that the height of the portion of the reaction medium 36 contained in the reaction zone 29 is Li and the height of the portion of the reaction medium 36 contained in the transition zone is Lt. In one embodiment, the height of the portion of the reaction medium 36 located in the upper reaction zone 31 is Lu. However, in certain cases the height of the reaction medium 36 in the upper reaction zone 31 may be less than Lu. In other cases, the total height of the reaction medium 36 may extend above the upper end 50 of the upper reaction zone 31 (ie, the total height of the reaction medium 36 is more than the sum of Li plus Lt plus Lu Preferably, the total height of the reaction medium is within 50, 25, or 10 percent of Lu measured either above or below the upper end 50 of the upper zone 31. Preferably, the oxidation bubbling column reactor 20 has a relation L ?: Lu in the range from about 0.05: 1 to about 5: 1, more preferably in the range from about 0.1: 1 to about 2.5: 1, and most preferably in the range of 0.15: 1 to 1.5: 1. Preferably, the oxidation bubble column reactor 20 has a Li: Dx ratio greater than about 0.5: 1, more preferably in the range of about 1: 1 to about 10: 1, and most preferably in the range of 1.5: 1 to 8: 1. The oxidation bubbling column reactor 20 preferably has a LU: DU ratio greater than about 2: 1, more preferably in the range of about 2.5: 1 to about 20: 1, and most preferably in the range of 3: 1. to 15: 1. In a preferred embodiment of the present invention Lx is at least about 2 meters, more preferably Li is in the range of about 4 about 50 meters, and much more preferably in the range of 6 to 40 meters. Preferably, Lu is at least about 4 meters, more preferably in the range of about 5 to about 80 meters, and much more preferably in the range of 10 to 60 meters. Preferably D ^. it is in the range of about 2 to about 12 meters, more preferably in the range of about 3.1 to about 10 meters, and much more preferably in the range of 4 to 9 meters.

FIG. 32 also illustrates that the oxidation bubble column reactor 20 has a decoupling section 26 located above the upper reaction section 31. The decoupling section 26 defines the decoupling zone 30. As shown in FIG. 32, decoupling zone 30 has a maximum height "Y" and a maximum width "X". It is preferred that the oxidation bubble column reactor 20 have an X: D? in the range of about 0.8: 1 to about 4: 1, much more preferably in the range of 1.1: 1 to 2: 1. The oxidation bubbling column reactor 20 preferably has an LU: Y ratio in the range of about 1: 1 to about 10: 1, much more preferably in the range of 2: 1 to 5: 1. The oxidation bubbling column reactor 20 preferably has an L?, - Y ratio in the range of about 0.4: 1 to about 0: 1, most preferably in the range of 0.6: 1 to 4: 1. The transition section 27 of the container shell 22 has a maximum diameter "Di" adjacent to the lower section 23 and the maximum diameter "Du" adjacent to the upper section 25. The oxidation bubble column reactor 20 preferably has a Lt ratio: D? in the range of about 0.05: 1 about 5: 1, much more preferably in the range of 0.1: 1 to 2: 1.

The vertically varying horizontal cross-sectional area of the oxidation bubble column reactor 20 illustrated in FIG. 32 provides the portion of the reaction medium 36 contained in the upper reaction zone 31 with a higher gas surface velocity and higher gas containment than the portion of the reaction medium 36 contained in the lower reaction zone 29. Preferably, the speed of the surface gas averaged over time of the portion of the reaction medium 36 contained in the upper reaction zone 31 at half the height of the reaction medium in the upper reaction zone 31 is at least about 15 percent higher that the surface gas velocity averaged over time of the portion of the reaction medium 36 contained in the lower reaction zone 29 in half the height of the reaction medium in the reaction zone 29. More preferably, the portion of the medium of reaction 36 contained in the reaction zone 31 has a surface gas velocity averaged over time at half the height of the reaction medium in the zone of upper reaction 31 which is in the range of about 25 to about 210 weight percent greater than the surface gas averaged in time from the portion of the reaction medium 36 contained in the lower reaction zone 29 in half the height of the reaction medium in the reaction zone 29. Much more preferably, the time-averaged surface gas velocity of the portion of the reaction medium 36 contained in the upper reaction zone 31 at half the height of the reaction medium in the upper reaction zone 31 is in the range of 35 to 160 percent greater than the surface gas velocity averaged in time from the portion of the reaction medium 36 contained in the lower reaction zone 29 at half the height of the reaction medium in the reaction zone 29. Preferably, the containment of the gas averaged in time and averaged in volume of the portion of the reaction medium contained in the upper reaction zone 31 is at least about 4 percent greater than the gas containment averaged in time and averaged in volume of the portion of the medium of reaction 36 contained in a lower reaction zone 29. More preferably, the gas containment averaged in time and averaged in volume of the portion of the reaction medium 36 contained in the upper reaction zone 31 is in the range of about 6 to about 80 percent greater than the volume-averaged and averaged volume-containing gas containment of the portion of the reaction medium 36 contained in an lower reaction 29. Much more preferably, the gas containment averaged over time and averaged by volume of the portion of the reaction medium 36 contained in the upper reaction zone 31 is in the range from 8 to 70 percent greater than the gas averaged in time and averaged in volume from the portion of the reaction medium 36 contained in a lower reaction zone 29. Although FIG. 32 illustrates a very specific, two-stage, cylindrical side wall bubbling column design, it should be understood that many other designs may fall within the scope of this embodiment of the invention. For example, the narrow upper and lower to broad sections of the reactor may be formed of one or more inclined side walls and / or a plurality of sidewall segments of stage diameter. In each case the claims, not the drawings capture the essence of this modality. As mentioned in the above, in certain cases, it may be desirable to employ larger bubble column reactors in order to allow the higher production ratios for a single reactor. However, as the size of the bubbling reactors increases, the fluid flow behavior of the multiple phase reaction medium contained therein changes significantly from the flow behavior of the smaller reactors. It has been discovered that changing the behavior of the fluid flow of the larger bubble column reactors can be counteracted by contacting the multi-phase reaction medium contained in the Bubbling column with additional vertical surfaces. Accordingly, FIGS. 33-44 illustrate several routes to provide the additional vertical surface area in the reaction zone of an enlarged-scale bubble column reactor. Each of the bubble column reactors illustrated in FIGS. 33-44 include one or more vertical internal members contained in the reaction zone of the bubble column reactor. These vertical internal members are provided in addition to the side walls containing vertical pressure of the reactor. As previously discussed, the reaction medium contained in the bubble column reactor has a maximum height "H" and a maximum width "W". The minimum width of the reaction medium that occurs above a height of H / 5 is referred to herein as "Wmin". In a preferred embodiment of the present invention the total vertical surface area of the bubble column reactor that contacts the reaction medium is preferably greater than about 3.25 WminH, more preferably in the range of about 3.5 minH to about 20WminH, still more preferably in the range of about 4WminH to about 15WminH, and most preferably in the range of 5WminH to lOWminH. The total vertical surface area that makes contact with the reaction medium includes the entire area of the vertical surfaces, including the vertical surfaces of the vertical wall of the pressure-containing reactor and the vertical surfaces of any of the internal members present within the reaction zone. As used herein the term "vertical" denotes less than 45 ° from the vertical, preferably, the vertical surfaces contacting the reaction medium in the bubble column reactor extend at an angle within 30 ° of the vertical, more preferably within 15 ° of the vertical, still more preferably within 5o of the vertical, and much more preferably substantially vertical. It is further preferred that the total amount of vertical surface area contacting the reaction medium that is attributable to internal members that do not contain pressure is at least about 10 percent of the total amount of vertical surface area that makes contact with the reaction medium that is attributable to the side walls containing container pressure. More preferably, total exposed vertical surface area presented by the inner members and contacting the reaction medium are in the range of about 15 to about 600 percent of the total exposed vertical surface area presented by the side walls containing pressure and which make contact with the reaction medium, still more preferably in the range of about 25 to about 400 percent, and much more preferably in the range of 35 to 200 percent. The presence of the vertical surface area added in the bubble column oxidation may allow lower H: W ratios that would be possible in conventional bubble column reactors having little or no vertical surface area added. Thus, it is preferred that the H: W ratio of a bubble column reactor employing the added vertical surface area that is in the range of about 3: 1 to about 20: 1, more preferably in the range of about 3.5: 1 to about 15: 1 and much more preferably in the range of 4: 1 to 12: 1. Referring now to the embodiment illustrated in FIGS 33 and 34, the oxidation bubbling column reactor 20 may include a single dividing wall 33 extending diametrically from one side of the side wall 46 to the opposite side of the side wall 46. The divider wall 33 is placed above the spray tube 34 so that substantially all of the oxidant stream is introduced below the bottom of the partition wall 33. Thus, about one half of the gas phase of the reaction medium 36, which includes an undissolved portion of the oxidant stream flows upward on each side of the partition wall 33. Preferably, about one half of the flow of feed is introduced via the feed inlet 32a on one side of the dividing wall 33, and the other side of the feed stream is introduced via the feed inlet 32b on the other side of the dividing wall 33 The height of the dividing wall 33 is substantially equal to the height of the cylindrical side wall 46. The dividing wall 33 divides the reaction zone 28 into about 2 halves with the reaction medium 36 which is placed on each side of the wall. divider 33. Substantially all of the vertical surface area of the reactor 20 that contacts the reaction medium 36 is attributable to the internal exposed surfaces of the side wall 46 and the external exposed surfaces of the partition wall 33. If the partition wall 33 was not present in the reaction zone 28, then substantially all of the vertical surface area in contact with the reaction medium 36 would be attributable to the walls beating 46 of the pressure vessel holding shell 22. The divider wall 33 provides the additional surface area that affects the fluid flow dynamics of the reaction medium 36 and allows the oxidation bubble column reactor 20 to be of increased scale without the significant negative effects on reactor performance. With reference now to the modality illustrated in FIG. 35, the oxidation bubble column reactor 20 is illustrated as already including a truncated divider wall 35. The divider wall 35 of FIG. 35 is similar to the dividing wall 33 of FIGS. 33 and 34; however, the divider wall 35 of FIG. 35 has a height that is significantly less than the total height of the reaction medium 36. In the configuration illustrated in FIG. 35, it is preferred that substantially all of the feed stream and the oxidant stream are introduced into the reaction zone 28 below the bottom of the partition wall 35. The upper part of the partition wall 35 is preferably spaced a substantial distance from the upper surface 44 of the reaction medium 36. In this configuration the two halves of the reaction medium 36 placed on each side of the dividing wall 35 can be mixed together above and below the dividing wall 35. Referring now to the embodiment illustrated in FIG. FIGS. 36 and 37, the oxidation bubbling column reactor 20 may include a non-planar divider wall 37 that allows a substantial amount of the vertical surface area to be added to the reactor 20, without requiring a plurality of additional internal members in the reaction zone. 28. Similar partition walls, 33, 35 of FIGS. 33-35, the dividing wall 37 of FIGS. 36 and 37 are attached to and extend between the wall surfaces internal diametrically opposite side of the side wall 46. In the embodiment illustrated in FIGS 39 and 39, the oxidation bubble column reactor 20 includes a vertical inner member 41 having a generally X-shaped configuration. The outer vertical edges of the inner member 41 are spaced inwardly from the inner surfaces of the side wall 46 so that the reaction medium 36 can flow between the partial quadrants defined by the X-shaped internal member 41. The various exposed external vertical surfaces of the member internal 71 add a significant amount of the surface area that makes contact with the reaction medium 36. FIGS. 40-42 illustrate an embodiment wherein a portion of the reaction zone 28 is divided into 4 vertical quadrants via the internal member 53, while another portion of the reaction zone 28 is divided into 8 vertical wedge-shaped sections by the path of the inner member 55. As illustrated in FIG. 40, the reaction zone 28 vertically alternates between the division and the four vertical quadrants with the inner member 53 and 8 vertical wedge-shaped sections via the internal member 55. Referring now to FIGS. 43 and 44, the Oxidation bubble column reactor 20 is illustrated as including a plurality of generally helically-shaped internal members 61a, b, c, d and a vertical X-shaped divider member 63 positioned above the helical members 61. The helical members 61 present on the inclined outer surfaces that induce a turbulent flow pattern in the upstream portion of the reaction member 36. It is preferred that the direction of inclination of the helical members 61 be such that the adjacent helical members 61 cause the turbulence of reaction medium 36 in the generally opposite directions. Thus, if the helical member 61a causes the reaction medium to rotate clockwise as the reaction medium rises in the reaction zone 28, the helical member 61b (positioned immediately above the helical member 61a) causes the reaction means moving upwards 36 swirling in an anti-clockwise manner. The vertical internal divider member 93 adds the additional vertical surface area to the oxidation column reactor 20, and may also function to minimize swirl / turbulence formation of the reaction medium 36 as the gas phase rises toward the upper surface 44 of the reaction medium 36. Without considering that configuration illustrated in FIGS 33-44 is employed in the oxidation bubbling column reactor 20, it is preferred that the oxidant stream and the feed stream are introduced into the reaction zone 28 in such a way that a substantial portion of the molecular oxygen and the oxidizable compound are introduced into the reaction zone 28 below a significant portion of the vertical internal member or members. Preferably at least about 50 weight percent of all molecular oxygen and the oxidizable compound introduced in the reaction zone 28 enter the reaction zone 28 below at least 50 percent of the member's exposed external surface area. or inner members, more preferably at least about 75 weight percent of molecular oxygen and the oxidizable compound between e to the reaction zone below at least 50 percent of the vertical exposed external surface area of the inner member (s), still more preferably at least about 90 weight percent of the molecular oxygen and the oxidizable compound enter the reaction zone below at least 50 percent of the vertical exposed external surface area of the internal member (s) ( s), and much more preferably substantially all of the molecular oxygen and the oxidizable compound enter the reaction zone below. minus 50 percent of the vertical exposed external surface area of the inner member (s).

In addition, it is preferred that the oxidant stream and feed stream be introduced in such a way that a substantial portion of the gas phase of the reaction medium 36 flows upward on all sides of the additional exposed external surface area provided by the member or internal members. It is preferred that additionally the oxidant streams and the feed are introduced into the reaction zone 28 according to the radial and azimuth distribution schemes described in the above. Although certain oxidation reactors of the prior art may employ heat exchange surfaces that contact the reaction medium in a manner similar to that of the internal member (s) described herein. It should be mentioned that it is undesirable for the internal member (s) of the present invention to provide any significant degree of heating or cooling to the reaction medium. Thus, it is preferred that the heat flow of the exposed vertical surfaces (i.e., contacting the reaction medium) of the internal member (s) described herein is less than about 30,000 watts per meter. square. FIGS 45-53 illustrate embodiments of the present invention where the oxidation bubble column reactor 20 is equipped with one or more deviators that make contact with the multi-phase reaction medium. in order to facilitate improved oxidation with minimal impurity formation. The diverters are especially useful in the enlarged scale bubble column reactor designs described in the foregoing. In each of the bubble column reactors diverters 20 illustrated in FIGS. 45-53, it is preferred that the diverter or diverters have an open area in the range of about 10 to about 90 percent. As used herein, the open percent area of a diverter means the minimum percent of the horizontal cross sectional area of a reaction zone that is open (ie not filled by the diverter structure) at the vertical location of the diverter. More preferably the open area of the diverter or diverters illustrated in FIGS. 45-53 is in the range of about 25 to about 75 percent, much more preferably in the range of 35 to 65 percent. A significant feature of the derailleurs illustrated in FIGS 45-53 is the ability of derailleurs to resist fouling. A previously mentioned oxidation bubble column reactor 20 is preferably employed in precipitation of the oxidation service, where the solids are formed in the reaction medium 36 during oxidation. Derailleurs that have a significant amount of flat surface area facing up close to horizontal are prone to fouling in a reactor operation under precipitation conditions. When diverters become dirty, solids accumulate on the facing surfaces of diverters, and as the amount of solids deposited on the diverters increases, pieces of the precipitated solids can be dislodged from the diverters and fall to the bottom of the diverter. reactor. These pieces of dislodged solids can accumulate at the bottom of the reactor and can cause a number of problems including, for example, the inhibition of the suspension discharge out of the bottom of the reactor. In view of the foregoing, it is preferred in one embodiment for the diverter or diverters employed in the oxidation bubble column reactor 20 to have any of the flat external surfaces facing upwards (for example, the diverter can be constructed of materials of pipes that have a circular cross section). Unless defined otherwise in the present, a surface facing upwards is a surface having a normal vector projection above the horizontal. In another embodiment, a small amount of the substantially planar surfaces can be used while less than about 50 percent of the exposed external surface area facing up total The deviator or derailleur is attributable to the substantially flat surface inclined minus 30 °, or 20 °, or even 10 ° from the horizontal. More preferably, less than about 35 percent of the total exposed outer surface area facing upwards of the diverter or diverters is attributable to flat surfaces inclined less than 30 °, or 20 °, or even 10 ° from the horizontal. Much more preferably, less than 25 percent of the exposed external surface area facing upward of the diverter or diverters is attributable to substantially flat surfaces inclined less than 30 °, 20 °, or even 10 ° from the horizontal. It is further preferred that exposed external surfaces facing upwardly of the diverter or diverters have a substantially smooth finish in order to additionally resist fouling. Preferably, at least a substantial portion of the exposed outer surfaces facing upward of the diverter or diverters has a rough surface of less than about 125 MRS, more preferably less than about 64 MRS, and most preferably less than 32 MRS. Electro-polished finishes and finishes with smooth "2B" mill roller are particularly useful. In addition to the non-fouling design of the derailleur or diverters illustrated in FIGS. 45-53, it is preferred that the diverter (s) is appropriately spaced from the upper and lower ends of the reaction means 36 to provide optimized effectiveness. In a preferred embodiment of the present invention the diverter or deviators are placed at least 0.5W and / or 0.05H from both the upper and lower ends of the reaction medium 36, where "" in maximum width of the reaction medium 36 and "" HW is the maximum height of the reaction medium 36. More preferably, the diverter or diverters are spaced by at least 1W and / or 0.1H from both the upper and lower ends of the reaction medium 36. Much more preferably, the diverter and the deviators are spaced at least 1.5 W and / or 0.15H from both the upper and lower ends of the reaction medium 36. The presence of a deviator or deviators in the oxidation bubble column reactor 20 may allow lower H: W ratios Thus, it is preferred that the H: W ratio of the deviator bubble column reactors be in the range of about 3: 1 to about 20: 1, more preferred. in the range of about 3.5: 1 to about 15: 1, and much more preferably in the range of 4: 1 to 12: 1. Referring now to FIGS 45-47 in detail, the oxidation bubble column reactor 20 is illustrated as it includes a plurality of deflectors vertically spaced 71a, b, c, d. preferably, the oxidation bubble column reactor 20 includes in the range of 2 to 20 vertically spaced deviators, most preferably from 3 to 8 vertically spaced deviators. Preferably, each diverter 71 comprises a plurality of elongated individual diverter members 73. In this embodiment, each individual diverter member 73 has an exposed substantially cylindrical external surface contacting the means of. reaction 36. In the embodiment illustrated in FIGS. 45-47, the diverters 71a, b, c, d are rotated relative to one another so that the individual diverter members 73 of the adjacent diverters 71 extend substantially perpendicular to each other. With reference now to FIGS. 48-50 in detail, the reciprocating deviators 81a, b, c, d are illustrated as comprising a plurality of individual diverter members 83. In this embodiment, each diverter member 83 is formed of a member of section L and presents an external surface exposed face up in V shape usually inverted. The configuration of the exposed external surfaces of the individual diverter members 83 helps to prevent fouling with the precipitation of solids in the reaction medium 83. The number, spacing, and orientation of the angled scout members. 83 may be substantially the same as described above for the cylindrical diverter members 73 of FIGS. 45-46. Referring now to FIGS 51-53 in detail, the oxidation bubble column reactor 20 is illustrated as including a single monolithic diverter 91 which is generally in the form of two opposite-extending vertical cones 93a, b linked in its base. The inclination of the exposed upwardly exposed external surface of the monolithic diverter 91 helps to prevent fouling of the diverter 91 with the precipitation of solids in the reaction medium 36. The various diverter configurations illustrated in FIGS 45-53 are exemplary only, and many other diverter configurations may fall within the scope of the present invention. It should also be mentioned that the diverting configurations illustrated in FIGS. 45-53 can be used in combination. Although certain combination reactors of the prior art can employ heat exchange tubes that make contact with the reaction medium in a manner similar to that of the diverter (s) described herein, it should be mentioned that it is undesirable for the deviators of the present invention to provide any significant degree of heating or cooling of the medium of reaction. Thus, it is preferred that the heat flow of the exposed external surfaces (i.e. contacting the reaction medium) of the diverters described herein are less than about 30,000 watts per square meter. With reference now to FIG. 54, in one embodiment of the present invention, the oxidant stream is introduced into the reaction zone 28 of the bubble column reactor 20 via a plurality of vertically spaced oxidant inlets 98a, b, c, d. The introduction of the oxidant stream from the multiple vertical locations can allow adjustment of the temperature and / or oxygen concentration and / or the liquid and gas flow patterns in various parts of the reaction medium 36. In addition, it can be It is useful to admit the oxygen to the reaction medium 36 in several vertical locations in order to control the flammability, reaction rate, and / or selectivity in various parts of the reaction medium 36. Additional control can be provided by adjusting the flow rate of the reaction medium. the oxidant stream through oxidant inlets 98a, b, c, d through the pathways of control valves 99a, b, c, d. Although FIG. 54 schematically illustrates the multiple feed inputs 98a, b, c, d that the vessel shell penetrated into the locations vertically With multiple spacings, it should be understood that a variety of internal oxidant dispersion media can be used to introduce the oxidant stream at several elevations in the reaction zone 28 without requiring multiple container penetrations. For example, the bubble column reactor 20 could include two or more vertically spaced sprinkler tubes, each having a configuration similar to the sprinkler tube 34, illustrated in FIGS. 2-5, and / or the spray tube 200, illustrated in FIGS. 12-15. Alternatively, the oxidant stream could be introduced into the reaction zone 28 at multiple elevations in a manner similar to that disclosed in the above to introduce the feed stream into the reaction zone 28 at multiple elevations. Thus, distribution systems similar to those illustrated in FIGS 6-18 could also be used to distribute the oxidant stream in the reaction zone 28. Without considering the specific configuration of the system used to introduce the oxidant stream into the zone of reaction 28, it is preferred that a stream of oxidant comprising molecular oxygen to enter the reaction zone 28 via a plurality of oxidant orifices, at least two of which are vertically spaced apart from each other by at least about 1W and / or 0. 15H, where "W" is the maximum width and "H" is the maximum height of the reaction medium 36. More preferably, at least two of the oxidation orifices are vertically spaced from each other by at least about 2W and / or 0.25H . Most preferably, at least two of the oxidation ports are spaced vertically from each other by at least 3W and / or 0.4H. It is preferred that the oxidant streams entering the reaction zone 28 via the vertically spaced oxidant orifices described above have substantially the same oxygen concentration, preferably, all of the vertically spaced oxidant streams comprise less of about 50 mole percent molecular oxygen, more preferably less than about 40 percent molecular oxygen, still more preferably in the range of about 18 to about 24 mole percent molecular oxygen. Much more preferably, the oxidant streams are air. It is preferred that at least about 10 mole percent, or about 20 mole percent, or even 40 mole percent of all the molecular oxygen introduced in the reaction 28 enter the reaction zone 28 within about 0.5W and / or 0.05H from bottom 52 of the reaction zone 28. More preferably, at least about 10 mole percent, or about 20 percent in mole, or even 40 mole percent of all the molecular oxygen introduced into the reaction zone 28 between the reaction zone 28 within 0.25 W and / or 0.025H from the bottom 52 of the reaction zone 28. Preferred that at least about 10 mole percent, or about 20 mole percent, or even 40 mole percent of all the molecular oxygen introduced in the reaction 28 enters the reaction zone 28 at the vertically spaced location (s) above the bottom 52 of the reaction zone 28 by at least about 1.5W and / or 0.15H. More preferably, at least about 10 mole percent, or about 20 mole percent, or even 40 mole percent of all the molecular oxygen introduced in the reaction 28 enters the reaction zone 28 at a location or locations vertically spaced from the bottom 52 of the reaction zone 28 by at least 2W and / or 0.2H. As alluded to above, the concentration of oxygen in the liquid phase of the reaction medium 36 can be adjusted at various elevations by introducing the oxidant stream in multiple vertically spaced locations. As discussed previously, the reaction medium 36 may have a vertically variant oxygen concentration gradient. It is preferred that a portion of the oxidant stream is introduced into the reaction zone 28 at an elevation at or above the elevation where the concentration of oxygen in the reaction medium 36 falls below 60% of the maximum oxygen concentrations in the reaction medium 36. In order to define the location of the orifice (s) of high oxidant used to introduce the oxidant stream into or above from the location of the low oxygen concentration, the reaction medium 36 can theoretically be divided into 30 discrete horizontal cuts of equal volume and the oxygen concentration of each horizontal cut can be determined on a wet molar basis averaged over time and averaged over volume. The horizontal cutoff with the highest oxygen concentration can be identified as the horizontal cut 02-max. The first horizontal cut above the horizontal cut 02-max having an oxygen concentration that is less than 60 percent of the oxygen concentration of the horizontal cut 02-max is defined as the horizontal cut-off 02-threshold. It is preferred that the horizontal cut 02-max be one of the bottom of 10 horizontal cuts, much more preferably one of the bottom of 5 horizontal cuts. It is preferred that the horizontal cut 02-threshold be one of the means of 20 horizontal cuts, much more preferably one of the medium of 14 horizontal cuts, it is preferred that the cut 02 ~ threshold be located at least 2 horizontal cuts above the horizontal cut 02 -max, much more preferably at least 4 horizontal cuts above the horizontal cut 02-max, and much more preferably by at least 6 horizontal cuts above the horizontal cut 02-max. It is preferred that at least a portion of the oxidant stream be introduced into the reaction zone 28 via an oxidant orifice (s) placed at or above the 02-threshold cutoff, preferably 5 weight percent, percent by weight, or even 25 percent by weight of all the molecular oxygen introduced into the reaction zone 28 enters the reaction zone 28 at or above the horizontal cut-off 02-threshold. The temperature of the reaction medium 36 at various elevations can also be adjusted by introducing the oxidant stream at multiple vertically spaced locations. As discussed previously, the reaction medium 36 can stop a vertically varying temperature gradient. It is preferred that a portion of the oxidant stream is introduced into the reaction zone 28 at an elevation at or above the elevation where the temperature of the reaction medium is increased by an undesirable amount above the minimum temperature in the bottom half. of the reaction medium 36. In order to define the location of the orifice (s) of high oxidant used to introduce the oxidant stream, the reaction medium 36 can theoretically be divided into 30 discrete horizontal cuts of equal volume and the temperature of each horizontal cut can be determined on an averaged basis in time and averaged in volume. The horizontal cut of the bottom of 15 horizontal cuts that have the lowest temperature can be identified as the horizontal cut T-min. The first runs above the horizontal cut T-mm which has undesirably high temperature can be identified as the horizontal cut T-threshold. It is preferred that the horizontal cutting temperature T-threshold be at least about 1 ° C higher than the horizontal cutting temperature T-rnin, more preferably at least 2 ° C higher than the horizontal cutting temperature T-min, and much more preferably at least 3 ° C higher than the horizontal cutting temperature T-mm. It is preferred that the horizontal cut T-min be one of the bottom of 10 horizontal cuts, much more preferably one of the bottom of 5 horizontal cuts. It is preferred that the horizontal cut-out T-threshold be one of the means of 20 horizontal cuts, much more preferably one of the medium of 14 horizontal cuts. It is preferred that the T-threshold cut be located at least two horizontal cuts above the horizontal cut Tm, much more preferably at least 4 horizontal cuts above the horizontal cut T-min, and much more preferably at least 6 horizontal cuts above of the horizontal cut T-min. It is preferred that at least a portion of the oxidant stream be introduced into the reaction zone 28 via an oxidant orifice (s) placed at or above the T-cut. threshold. Preferably, 5 percent by weight, 10 percent by weight, or even 25% by weight of all molecular oxygen in the reaction zone 28 between the reaction zone 28 at or above the horizontal cut-off T-threshold. In addition to the vertical distribution of the oxidant stream described immediately above, it is preferred that the oxidant stream be distributed azimuthally and radially in the manner previously described. In addition, the radial and azimuthal distribution of the oxidant stream introductions can be used to reconfigure the natural convection flow patterns within the reaction medium of an oxidation bubbling column. The normal pattern of natural convection flows will be greatly restored by themselves within two or three column diameters, open and unimpeded, above a high input of oxidant, but local disruption can provide important control over the formation of vertical stages of oxidant and the oxidizable compound. Conceptually, the azimuthal and radial positioning of the introduction of the oxidant stream can be adjusted to provide more or less hydraulic deflection of the reaction medium. In a preferred embodiment using a high oxidant inlet to provide the hydraulic bypass, the inlet is used to increase the vertical stage formation by reducing the side-by-side mixing of the liquid phase as follows. It is preferred that the high input of the oxidant stream releases at least about 60 percent, more preferably at least about 80 percent, much more preferably substantially all of its external flow of 60 percent, more preferably 70 percent. one hundred percent, much more preferably 80 percent of the cross-sectional area closest to the horizontal centroid of the reaction medium in the elevation of the local entrance to such an external diameter oxidant inlet, the increased presence of the oxidant flowing upwards near the reaction vessel walls will serve to resist and retard the liquid or suspension phase that flows down along the walls, averaged over time. In a more preferred embodiment, the flowing open area of such and the high external diameter oxidant inlet is largely directed at or above the horizontal, preferably more than 50 percent of the open area, more preferably more than 70 percent, and much more preferably more than 90 percent. In a more preferred embodiment using the high oxidant inlet to provide the hydraulic bypass, the inlet is used to increase the vertical stage formation by reducing side-by-side mixing side of the liquid phase as follows. It is more preferred that the high input of the oxidant stream releases at least about 60 percent, more preferably at least about 80 percent, much more preferably substantially all of its direct flow horizontally and below the horizontal and located within 70 percent, more preferably 60 percent, much more preferably 50 percent of the cross-sectional area closest to the horizontal centroid of the reaction medium at the elevation of the entrance. Local to such an internal diameter oxidation inlet, the horizontal moment downward of the incoming oxidant stream will resist and retard the flow of the reaction medium flowing upward through the core of the reaction vessel, averaged over time. In a much more preferred embodiment, more than 50 percent, more preferably more than 70 percent, and much more preferably more than 90 percent open flowing area of such high internal diameter oxidant input is directed downwardly within approximately 60 degrees, more preferably within about 45 degrees and much more preferably within 30 degrees of vertical. With reference again to FIGS. 1-54, the oxidation is preferably carried out in the bubble column reactor under conditions which are markedly different according to the preferred embodiments disclosed herein, than conventional oxidation reactors. When the bubble column reactor 20 is used to carry out the partial liquid-phase oxidation of the para-xylene to the crude terephthalic acid (CTA) according to preferred embodiments disclosed herein, the spatial profiles of the local intensity, of the local evaporation intensity and the local temperature combined with the liquid flow patterns within the reaction medium and the relatively low, preferred oxidation temperatures contribute to the formation of CTA particles having unique and advantageous properties. FIGS. 55A and 55B illustrate base CTA particles produced in accordance with one embodiment of the present invention. FIG. 55A shows the CTA base particles in 500 times of enlargement, while FIG. 54B approaches in one of the base CTA particles and shows that particle at 2000 times of enlargement. As perhaps better illustrated in FIG. 55B, each base CTA particle is typically formed from a large number of small agglomerated CTA sub-particles, thus giving the CTA base particle a relatively high surface area, high porosity, low density, and good solvent capacity. The CTA base particles typically have an average particle size in the range of about 20 to about 150 microns, more preferably in the range of about 30 to about 120 microns, and most preferably in the range of 40 to 90 microns. CTA sub-particles typically have an average particle size in the range of about 0.5 to about 30 microns, more preferably from about 1 to about 15 microns, and most preferably in the range of 2 to 5 microns. The relatively high surface area of the base CTA particles illustrated in FIGS 55A and 55B can be quantified using a Braimaier-Emmett-Teller (BET) surface area measurement method. Preferably, the base CTA particles have an average BET surface of at least about 0.6 meters per square gram (m2 / g). More preferably, the base CTA particles have an average BET surface area in the range of about 0.8 to about 0.4 m2 / g. Much more preferably, the base CTA particles have an average BET surface area in the range of 0.9 to 2 m2 / g. The physical properties (eg, particle size, BET surface area, porosity and dissolution capacity) of the CTA particles formed by the optimized oxidation process of a preferred embodiment of the present invention allows the purification of the particles of CTA through more effective methods and / or economic, as described in further detail immediately with respect to FIG. 57. The mean particle size values provided in the above were determined using polarized light microscopy and image analysis. The equipment used in the particle size analysis included a Nikon E800 optical microscope with a 0.13 objective of n.A. Plan Fluor 4x, a Spot RT ™ digital camera, and a personal computer that runs image analysis and image software V4.5.0.19 Image Pro Plus ™. The particle size analysis method included the following main steps: (1) dispersion of CTA dust in mineral oil; (2) prepare a slide / cover microscope object of the dispersion; (3) examine the slide using polarized light microscopy (cross polar condition - the particles appear as bright objects on the black background); (4) capture the different images for each sample preparation (field size = 3 x 2.25 mm, pixel size = 1.84 microns / pixel); (5) perform image analysis with Image Pro Plus ™ software; (6) export the particle measurements to a spreadsheet; and (7) perform the statistical characterization in the spreadsheet. The stage (5) of the "image analysis of performance with the software Image Pro Plus ™" including the steps of: (a) adjust the image lumbral to detect white particles on the black background; (b) create a binary image; (c) run an open pass filter only to filter the noise of the outer pixel; (d) measure all the particles in the image; and (e) report the average diameter measured for each particle. The Image Pro Plus ™ software defines the average diameter of the individual particles as the average length of the number of diameters of a particle measured in a 2-degree interval and passing through the centroid of the particle. Stage 7 of "statistical characterization of performance at the time of calculation" comprises calculating the mean particle size weighed in volume as follows. The volume of each of the particles n in a sample is calculated as if they were spherical using pi / 6 * d? 3; multiply the volume of each particle times its diameter to find pi / 6 * d? 4; add all the particles in the sample of the values of pi / 6 * d? A4; add the volumes of all the particles in the sample; and calculating the particle diameter heavy in volume as sum for all particles n in the sample of (pi / 6 * d? A4) divided by the sum for all particles n in the sample (pi / 6 * d ?? 3 ). As used herein, "average particle size" refers to the average particle size weighed in volume determined according to the test method described above; and it is also preferred as D (4, 3).

In addition, step 7 comprises finding the particle sizes for which several fractions of the total sample volume are smaller. For example, 'D (v, 0.1) is the particle size whereby 10% of the total sample volume is smaller and 90 percent is larger; D (v, 0.5) is the particle size whereby one half of the volume of the sample is larger and one half is smaller; D (v, 0.9) is the particle size whereby 90 percent of the total sample volume is smaller; and so on. In addition, step 7 comprises calculating the value of D (v, 0.9) minus D (v, 0.1), which is defined herein as the "extent of particle size"; and step 7 comprises calculating the value of the particle size extension divided by D (4.3), which is defined herein as the "relative extent of particle size". In addition, it is preferable that the D (v, 0.1) of the CTA particles as measured in the above is in the range of about 5 about 65 microns, more preferably in the range of about 15 to about 55 microns and most preferably in the range of about 15 to about 55 microns. the interval of 25 to 45 microns. It is preferable that the D (v, 0.5) of the CTA particles as measured in the above is in the range of about 10 to about 90. microns, more preferably in the range of about 20 to about 80 microns, and most preferably in the range of 30 to 70 microns. It is preferable that the D (v.09) of the CTA particles as measured in the above is in the range of about 30 to about 150 microns, more preferably in the range of about 40 to about 150 microns, and most preferably in the range of about 40 to about 150 microns. the interval of 50 to 110 microns. It is preferable that the relative extent of the particle size be in the range of about 0.5 to about 2.0, more preferably in the range of about 0.6 to about 1.5 and much more preferably in the range of 0.7 to 1.3. The BET surface area values provided in the above were measured on a Micromeritics ASAP2000 (available from Micromeritics Instrument Corporation of Norcross, GA). In the first stage of the measurement process, 2 to 4 grams of the sample of the particles was weighed and dried under vacuum at 50 ° C. The sample was then placed on the test gas manifold and cooled to 77 ° K. An exotherm of nitrogen adsorption was measured at a minimum of 5 equilibrium pressures by exposing the sample to known volumes of nitrogen gas and the measurement of the pressure decreased. The equilibrium pressures were appropriately in the P / Po range = 0.01-0.20, where P is the equilibrium pressure and Po is the vapor pressure of liquid nitrogen at 767 ° K. The resulting isotherm is then plotted according to the following BET equation: where it goes is the volume of gas adsorbed by the sample in P, Vm is the volume of gas required to cover the entire surface of the sample with a monolayer of gas, and C is a constant. From this graph, Vm and C were determined. Vm then converted to a surface area using the cross-sectional area of the nitrogen at 77 ° K: A A = s Vm RT where s is the cross-sectional area of the nitrogen at 77 ° K, T is 77 ° K, and R is the gas constant. As alluded to above, the CTA formed according to one embodiment of the present invention exhibits superior dissolution properties against conventional CTA made by other processes. This improved dissolution ratio allows the inventive CTA to be purified by more efficient and / or more effective purification processes. The following description addresses the manner in which the proportion of the CTA solution can be quantified.

The rate of dissolution of a known quantity of solids in a known amount of solvent and a stirred mixture can be measured by various protocols. As used herein, the measurement method called the "regulated dissolution test" is defined as follows. An environmental pressure of approximately 0.1 megapascal is used throughout the regulated dissolution test. The ambient temperature used for the entire regulated dissolution test is approximately 22 ° C. In addition, the solids, solvents and the entire dissolution apparatus are completely thermally equilibrated at that temperature before the initial test, and there is no appreciable heating or cooling of the breaker or its contents during the dissolution time period. A portion of HPLC analytical grade solvent, fresh tetrahydrofuran (> 99.9 percent purity), then in the present THF, 250 grams of measurement is placed in a 400 milliliter glass cup of high clean KIMAX form (Kimble® part number 14020, Kimble / Kontes, Vineland, NJ), which is not isolated, smooth side, and generally cylindrical in shape. A magnetic stirring bar coated with Teflon (VWR part number 58948-230, approximately 1 inch long with 3/8-inch diameter, octagonal cross-section, VWR International, West Chester, PA 19380) is placed in the glass , where it naturally sits in the background. The sample is shaken using a Variomag® multi-point magnetic stirrer 15 (H &P Labortechnik AG, Oberschleissheim, Germany) at a setting of 800 revolutions per minute. This agitation begins no more than 5 minutes before the addition of the solids and continues stable for at least 30 minutes after the addition of the solids. A solid sample of crude or purified TPA particulate materials amounting to 250 milligrams is weighed on a non-adherent weighed tray. At a start time designated as t = 0, the heavy solids are all emptied at once into the stirred THF, and a stopwatch starts simultaneously. Properly done, the THF moistens the solids very quickly and forms a well-stirred suspension, diluted within 5 seconds. Subsequently, samples of this mixture are obtained in the following times, measured in minutes of T = 0: 0.08, 0.25, 0.50, 0.75, 1.00, 1.50, 2.00, 2.50, 3.00, 4.00, 5.00, 6.00, 8.00, 10.00, 15.00, and 30.00. Each small sample is removed from the well-stirred mixture, diluted using a new disposable syringe (Becton, Dikinson and Co, 5 milliliters, REF 30163, Frandlin Lakes, NJ0.7417). immediately upon withdrawal from the vessel, approximately 2 milliliters of the clear liquid sample is rapidly discharged through a new unused syringe filter (25 mm diameter, 0.45 microns, Gelman GHP Acrodisc GF®, Pall Corporation, Eas Hills, NY 11548) in a sample vial marked glass, new. The duration of each syringe filling, filter placement, and discharge into a sample vial is correctly less than about 5 seconds, and this interval is approximately initiated and completed within approximately 3 seconds each side of each target sampling time . Within approximately 5 minutes of each fill, the sample flasks are capped and maintained at approximately constant temperature until the next chemical analysis is performed. After the final sample is taken at a time past 30 minutes t = 0, all sixteen samples are analyzed for the amount of dissolved TPA using an HPLC-DAD method generally as described elsewhere within this description. However, in the present test, the calibration standards and the reported results are both based on milligrams of dissolved TPA per gram of THF solvent (later herein "ppm in THF"). For example, if all of the 250 milligrams of solids was very pure TPA and this complete amount was completely dissolved in the 250 grams of the THF solvent before a particular sample was taken, the correctly measured concentration would be approximately 1,000 ppm in THF . When the CTA according to the present invention is subjected to the regulated dissolution test described in above, it is preferred that a sample taken at one minute t = 0 be dissolved at a concentration of. less about 500 ppm in THF, more preferably at least 600 ppm in THF. For a sample taken in two minutes past t = 0, it is preferred that the CTA according to the present invention will dissolve at a concentration of at least about 700 ppm in THF, more preferably at least 750 ppm in THF. For a sample taken in past four minutes t = 0, it is preferred that the CTA according to the present invention will dissolve at a concentration of at least about 840 ppm in THF, more preferably at least 880 ppm in THF. The inventors have found that a relatively simple negative exponential growth model is useful for describing the time dependency of the complete data sets of a complete regulated dissolution test, notwithstanding the complexity of the particulate samples and the dissolution process. The form of the equation, then in the present, the "regulated dissolution model", is as follows: S = A + B * (1 - exp (-C * t)), where t = time in units of minutes: S = solubility in units of ppm in THF, at time t; exp = exponential function at the base of the logarithm natural of 2; A, B = constants returned in units of ppm in THF, where A is mainly related to the rapid dissolution of the smallest particles in very short time, and where the sum of A + B is related mainly to the total amount of the solution near the specified trial period; and C = a time constant returned in units of reciprocal minutes. The returned constants are adjusted to minimize the sum of the squares of the errors of the current data points and the corresponding model values, which the method is commonly called a "last frame" setting. A preferred software package to perform this data regression is JMP Relay 5.1.2 (SAS Institute Inc., JMP Software, SAS Campul Drive, Cary, NC 27513). When the CTA according to the present invention is tested with the regulated dissolution test and is adjusted to the regulated dissolution model described above, it is preferred that the CTA have a time constant "C" greater than about 0.5 reciprocal minutes, more preferably greater than about 0.6 reciprocal minutes and much more preferably greater than 0.7 reciprocal minutes.

FIGS. 56A and 56B illustrate a conventional CTA particle made by a conventional high temperature oxidation process in a continuous stirred tank reactor (CSTR). FIG. 56A shows the conventional CTA particle at 500 times of enlargement, while FIG. 56B approaches and shows the CTA particle at 2,000 times of enlargement. A visual comparison of the inventive CTA particles illustrated in FIGS 55A and 55B and the conventional CTA particle shown in FIGS. 56A and 56B shows that the conventional CTA particle has a higher density, lower surface area, lower porosity, and larger particle size than the inventive CTA particles. In fact, the conventional CTA represented in FIGS. 56A and 56B has an average particle size of about 205 microns and a BET surface area of about 0.57 m2 / g. FIG. 57 illustrates a conventional process for making purified terephthalic acid (PTA). In the conventional PTA process, para-xylene is partially oxidized in a mechanically stirred high temperature oxidation reactor 700. A suspension comprising CTA is removed from reactor 700 and then purified in a 702 purification system. PTA of the purification system 702 is introduced into a separation system 706 to separate and dry the PTA particles. The purification system 702 represents a large portion of the costs associated with the production of PTA particles by conventional methods. The purification system 702 generally includes a water addition / exchange system 708, a dissolution system 710, a hydrogenation system 712, and 3 separate crystallization vessels 704a, b, c. The water addition / exchange system 708, a substantial portion of mother liquor is displaced with water. After addition of water, the water / CTA suspension is introduced into the dissolution system 710 where the water / CTA mixture is heated until the CTA particles completely dissolve in the water. After dissolution of CTA, the CTA solution in water is subjected to hydrogenation in the hydrogenation system 712. The hydrogenated effluent from the hydrogenation system 712 is then subjected to 3 crystallization steps in crystallization vessels 704a, b, c, followed by separation of PTA in separation system 706. FIG. 58 illustrates an improved process for producing PTA employing a bubbling column oxidation reactor 800 configured in accordance with an embodiment of the present invention. An initial suspension comprising solid CTA particles and a liquid mother liquor is removed from reactor 800. Typically, the initial suspension may contain in the range of about 10 to about 50 percent by weight of solid CTA particles. With the rest that is liquid mother liquor. The solid CTA particles present in the initial suspension typically contain at least about 400 ppmw of 4-carboxybenzaldehyde (4-CBA), more typically at least about 800 ppmw of 4-CBA, and much more typically in the range of 1,000. at 15,000 ppmw of 4-CBA. The initial suspension removed from the reactor 800 is introduced into a purification system 802 to reduce the concentration of 4-CBA and other impurities present in the CTA. A purer / purified suspension is produced from the purification system 802 and subjected to separation and drying in separation system 804 to thereby produce purer solid terephthalic acid particles comprising less than about 400 ppmw of 4-CBA , more preferably less than about 250 ppmw of 4-CBA, and much more preferably in the range of 1 to 200 ppmw of 4-CBA. The purification system 802 of the PTA production system illustrated in FIG. 58 provides a number of advantages over the purification system 802 of the prior art system illustrated in FIG. 57. preferably, the purification system 802 generally includes a liquor exchange system 806 a digester 808, and a crystallizer only 810. In the liquor exchange system 806, at least about 50 100 percent by weight of the mother liquor present in the initial suspension is replaced with a fresh replacement solvent to thereby provide a solvent-exchanged suspension that comprises CTA particles and the replacement solvent. The solvent-exchanged suspension leaving the liquor exchange system 806 is introduced into the digester (or secondary oxidation reactor) 808. In the digester 808, a secondary oxidation reaction is carried out at slightly higher temperatures than were used in the initial / primary oxidation reaction carried out in the bubble column reactor 800. As disclosed above, the high surface area, small particle size, and low density of the CTA particles produced in the 800 reactor cause certain impurities trapped in the CTA particles become available for oxidation in the digester 808 without requiring the complete dissolution of the CTA particles in the digester 808. Thus, the temperature in the digester 808 may be lower than many processes of the prior art Similar. The secondary oxidation carried out in the digester 808 preferably reduces the concentration of 4-CBA in the CTA by at least 200 ppmw, more preferably at least about 400 ppmw, and much more preferably in the range of 600 to 6,000 ppmw. Preferably, the secondary oxidation temperature in the digester 808 is at least about 10 ° C higher than the primary oxidation temperature in the bubble column reactor 800, more preferably approximately 20 approximately 80 ° C higher than the primary oxidation temperature in the reactor 800, and most preferably 30 to 50 ° C higher than the primary oxidation temperature in reactor 800. The secondary oxidation temperature is preferably in the range of about 160 to about 240 ° C, more preferably in the range of about 180 to about 220 ° C and most preferably in the interval from 190 to 210 ° C. The purified product from digester 808 requires only one crystallization step alone in crystallizer 810 prior to separation in separation system 804. Suitable secondary oxidation / digestion techniques are discussed in further detail in US Patent Application Publication No. 2005/0065373, the full description of which is expressly incorporated herein by reference. The terephthalic acid (e.g., PTA) produced by the system illustrated in FIG. 58 is preferably formed of PTA particles having an average particle size of at least about 40 microns, more preferably in the range of about .50 to about 2,000 microns, and most preferably in the range of 60 to 200 microns. PTA particles preferably it has an average BET surface area of less than about 0.25 m2 / g, more preferably in the range of from about 0.005 to about 0.2 m2 / g, and much more preferably in the range of 0.01 to 0.18 m2 / g. The PTA produced by the system illustrated in FIG. 58 is suitable for use as a feedstock in the manufacture of PET. Typically, PET is made by the esterification of terephthalic acid with ethylene glycol, followed by polycondensation. Preferably, the terephthalic acid produced by one embodiment of the present invention is used as a feed to the PET process of the tube reactor described in US Patent Application Serial No. 10 / 013,318, filed on December 7, 2001, the full description of which is incorporated herein by reference. CTA particles with the preferred morphology disclosed herein are particularly useful in the oxidative digestion process described above for the reduction of 4-CBA content. In addition, these preferred CTA particles provide advantages over a wide range of other post-processes involving the dissolution and / or chemical reaction of the particles. These additional post-processes include, but are not limited to, reaction, with at least one compound containing hydroxyl to form ester compounds, especially in the reaction of CTA with methanol to form dimethylterephthalate and impurity esters; reaction with at least one diol to form ester and / or polymer monomer compounds, especially the reaction of CTA with ethylene glycol to form polyethylene terephthalate; and complete or partial dissolution in solvents, including, but not limited to, water, acetic acid, and N-methyl-2-pyrrolidone, which may include additional processing including, but not limited to, reprecipitation of an acid purest terephthalic and / or selective chemical reduction of carbonyl groups other than carboxylic acid groups. Notably included is the substantial dissolution of CTA in a solvent comprising water coupled with partial hydrogenation which reduces the amount of aldehydes, especially 4-CBA, fluorenones, phenones, and / or anthraquinones. The inventors also contemplate that CTA particles having the preferred properties described herein can be produced from CTA particles that do not conform to the preferred properties disclosed herein (non-conformal CTA particles) by means including, but they are not limited to, mechanical trituration of CTA particles not of conformation and complete or partial dissolution of non conformation CTA particles followed by complete or partial reprecipitation.

According to one embodiment of the present invention, there is provided a process for partially oxidizing an oxidizable aromatic compound to one or more types of aromatic carboxylic acid wherein the purity of the solvent portion of the feed (i.e. "solvent" and the purity of the portion of the oxidizable feed compound (i.e., "oxidizable compound feed") is controlled within certain ranges specified below, together with other embodiments of the present invention, this allows the purity of the the liquid phase and, if present, the solid phase and the combined suspension phase (i.e. more liquid solid) of the reaction medium to be controlled at certain preferred ranges, summarized below With respect to the solvent feed, it is known oxidize an oxidizable aromatic compound (s) to produce an aromatic carboxylic acid where the solvent feed intro ducida in the reaction medium is a mixture of acetic acid of analytical purity and water, as is frequently used in laboratory scale and pilot scale. Similarly, it is known to conduct oxidation of the oxidizable aromatic compound to aromatic carboxylic acid wherein the solvent leaving the reaction medium is separated from the aromatic carboxylic acid produced and then recycled back to the reaction medium. as a feed solvent, mainly for reasons of manufacturing costs. This solvent recycling causes certain feed impurities and process by-products to accumulate over time in the recycled solvent. Various means are known in the art to aid in the purification of the recycled solvent prior to reintroduction into the reaction medium. Generally, a higher degree of purification of the recycled solvent leads to a manufacturing cost significantly higher than a lower degree of purification by similar means. One embodiment of the present invention relates to the understanding and definition of the preferred ranges of a large number of impurities within the solvent feed, many of which were hitherto widely believed to be benign, in order to find an optimum balance between the cost of complete manufacture and the purity of the complete product. "Recycled solvent feed" is defined herein as the solvent feed comprising at least about 5 weight percent mass that has previously passed through a reaction medium containing one or more oxidizable aromatics subject to partial oxidation. For reasons of solvent inventory and time in the stream in a manufacturing unit, it is preferable that the solvent portions recycled passes through the reaction medium at least once per day of operation, more preferably at least once per day for at least seven consecutive days of operation, and much more preferably at least once per day during minus 30 consecutive days of operation. For economic reasons, it is preferable that at least about 20 weight percent of the solvent feed to the reaction medium of the present invention recycle the solvent, more preferably at least about 40 weight percent, still more preferably so less about 80 weight percent, and much more preferably at least 90 weight percent. The inventors have discovered that, for reasons of reaction activity and for consideration of metal impurities left in the oxidation product, the concentrations of selected multivalent metals within the feed of the recycled solvent are preferably in the ranges specified immediately below. The concentration of iron in the recycled solvent is preferably below about 150 ppmw, more preferably below about 40 ppmw, and most preferably between 0 and 8 ppmw. The concentration of nickel in the recycled solvent is preferable below about 150 ppmw, more preferably below about 40 ppmw, and much more preferably between 0 and 8 ppmw. The concentration of chromium in the recycled solvent is preferably below about 150 ppmw, more preferably below about 40 ppmw, and most preferably between 0 and 8 ppmw. The concentration of molybdenum in the recycled solvent is preferably below about 75 ppmw, more preferably below about 20 ppmw, and most preferably between 0 and 4 ppmw. The concentration of titanium in the recycled solvent is preferably below about 75 ppmw, more preferably below about 20 ppmw, and much more preferably between 0 and 4 ppmw. The concentration of copper in the recycled solvent is preferable below about 20 ppmw, more preferably below about 4 ppmw, and much more preferably between 0 and 1 ppmw. Other metallic impurities are also typically present in the recycled solvent generally varying in lower levels in production to one or more of the metals listed in the foregoing. Control of the metals listed above at the preferred ranges will keep other metal impurities at suitable levels. These metals may arise as impurities in any of the incoming process feeds (e.g., in the oxidizable incoming compound, solvent, oxidant, and catalyst compounds). Alternatively, the Metals can arise as corrosion products from any of the process units that make contact with the reaction medium and / or make contact with the recycled solvent. Means for controlling metals in the disclosed concentration ranges include the proper specification and monitoring of the purity of various feeds and the proper use of construction materials, including, but not limited to, many commercial grades of titanium and steels stainless steels that include those grades known as double stainless steels and high molybdenum stainless steels. The inventors have also discovered preferred ranges for the selected aromatic compounds in the recycled solvent. These include both precipitated and dissolved aromatic compounds within the recycled solvent. Surprisingly, even the precipitated product (eg, TPA) of a partial oxidation of para-xylene is a contaminant that is handled in the recycled solvent. Because there are surprisingly preferred ranges for the levels of solids within the reaction medium, any product precipitated in the solvent feed directly is subtracted from the amount of oxidizable compound that can be fed into the convention. In addition, the feed of TPA solids precipitated in the recycled solvent in elevated levels have been discovered by adversely affecting the character of the particles formed within a precipitation oxidation medium, which leads to undesirable character in downstream operations (eg, product filtration, solvent washing, oxidized digestion of the crude product, dissolution of the crude product for further processing, and so on). Another undesirable characteristic of the solids precipitated in the feed of the recycled solvent is that they often contain very high levels of precipitated impurities, as compared to the concentrations of impurities in the volume of solids within the PTA suspensions of which many of the Recycled solvents are obtained. Possibly, the high levels of impurities observed in the suspended solids in the recycled filtrate can be related to the nucleation times for the precipitation of certain impurities from the recycled solvent and / or to the cooling of the recycled solvent, if it is intentional or due to losses environmental For example, highly colored and undesirable 2, 6-d? Carbox? Fluorenone concentrations have been observed at much higher levels in solids present in the recycled solvent at 80 ° C than are observed in the separated TPA solids in the recycled solvent at 160 ° C. Similarly, trisophthalic acid concentrations have been observed at much higher levels high in solids present in the recycled solvent compared to the levels observed in the PTA solids of the reaction medium. Exactly how precipitated impurities transported within the behavior of the recycled solvent when they are reintroduced into the reaction medium are presented to vary. This depends perhaps on the relative solubility of the impurity within the liquid phase of the reaction medium, perhaps on how the precipitated impurity is located within the precipitated solids, and perhaps on the local proportion of the TPA precipitation where the solid first reentrates the reaction medium. Thus, the inventors have found it useful to control the level of certain impurities in the recycled solvent, as disclosed below, without regard to whether these impurities are present in the recycled solvent in the dissolved form or are particulate materials transported therein. The amount of precipitated solids present in the recycled filtrate is determined by a gravimetric method as follows. A representative sample is removed from the solvent supply to the reaction medium while the solvent is flowed in a conduit to the reaction medium. A useful sample size is approximately 100 grams captured in a glass container having approximately 250 milliliters of internal volume. Before it is released at atmospheric pressure, but while flowing continuously to the sample container, the recycled filter material is cooled to less than 100 ° C; this cooling is in order to limit the evaporation of the solvent during the short interval before it closes sealed in the glass container. After the sample is captured at atmospheric pressure, the glass container is sealed immediately. The sample is then allowed to cool to approximately 20 ° C while being surrounded by air at about 20 ° C and without forced convection. After it reaches approximately 20 ° C, the sample is kept in this condition for at least about 2 hours. Then, the sealed container is shaken vigorously until a visible uniform distribution of solids is obtained. Immediately afterwards, a magnetic stir bar is added to the sample container and rotated at a sufficient speed to maintain the effectively uniform distribution of solids. An aliquot of 10 milliliters of liquid mixed with suspended solids is removed by pipetting and weighed. Then the volume of the liquid phase of this aliquot is separated by vacuum filtration, still approximately 20 ° C and effectively without loss of solids. The wet solids filtered from this aliquot are then dried, effectively without the sublimation of the solids, and these dry solids are weighed. The ratio of the weight of the dry solids to the weight of the original aliquot of the suspension is the fraction of solids, typically expressed as a percentage and is referred to herein as the recycled filtrate content of the solids precipitated at 20 ° C. The inventors have discovered that the aromatic compounds dissolved in the liquid phase of the reaction medium and comprising aromatic carboxylic acids lacking non-aromatic hydrocarbyl groups (for example, isophthalic acid, benzoic acid, italic acid, 2,5,4'- tricarboxylbiphenyl) are surprisingly pernicious components. Although these compounds are very reduced in chemical activity in the subject reaction medium compared to the oxidizable compounds having non-aromatic hydrocarbyl groups, the inventors have discovered that these compounds nevertheless undergo numerous harmful reactions. This is advantageous for controlling the content of these compounds at preferred intervals in the liquid phase of the reaction medium. This leads to preferred ranges of selected compounds in feed of the recycled solvent and also to preferred ranges of selected precursors in the feed of the oxidizable aromatic compound. For example, in the partial liquid phase oxidation of para-xylene to terephthalic acid (TPA), the inventors have discovered that 2,7-d? Carbox? Fluorenone from Highly colored and undesirable impurities (2,7-DCF) are virtually undetectable in the reaction medium and the intake of the product when the meta-substituted aromatic compounds are at very low levels in the reaction medium. The inventors have discovered that when the isophthalic acid impurity is present in levels of increase in the solvent feed, the formation of 2,7-DCF rises almost in the direct proportion. The inventors have also discovered that when the meta-xylene impurity is present in the para-xylene feed, the formation of 2,7-DCF again rises almost in the direct proportion. Furthermore, even if the solvent feed and oxidizable compound feed are free of meta-substituted aromatic compounds, the inventors have discovered that some isophthalic acid is formed during a partial oxidation typical of very pure para-xylene, particularly when the benzoic acid is present. in the liquid phase of the reaction medium. This self-generated isophthalic acid can, due to its greater solubility than TPA in the solvent comprising acetic acid and water, accumulate over time in commercial units employing recycled solvent. Thus, the amount of isophthalic acid within the solvent feed, the amount of meta-xylene within the feed of oxidizable aromatic compound and the rate of self-creation of isophthalic acid within the Reaction medium are all considered properly in balance with each other and in balance with any of the reactions that consume isophthalic acid. Isophthalic acid has been discovered to undergo additional constructive relationships in addition to the formation of 2,7-DCF, as disclosed below. In addition, the inventors have discovered that there are other problems to consider when appropriate sizing ranges for the aromatic species substituted in the partial oxidation of para-xylene to TPA. Other highly colored and undesirable impurities, such as 2, 6-d? Carbox? Fluorenone (2,6-DCF), seem to be greatly related to aromatic species for substituted, dissolved, which are always present with the feed of para-xylene to a oxidation in liquid phase. Thus, the suppression of 2,6-DCF is considered better in perspective with the level of other colored impurities that are being produced. For example, in the partial liquid phase oxidation of para-xylene to TPA the inventors have discovered that the formation of trimellitic acid rises as the levels of isophthalic acid and phthalic acid rise within the reaction medium. Trimellitic acid is a functional carboxylic acid that leads to the branching of polymer chains during PET production of TPA. In many PET applications, the branching levels are they should be controlled at low levels and therefore trimellitic acid should be controlled at low levels in the purified TPA. In addition, to lead to trimellitic acid, the presence of the meta-substituted and ortho-substituted species in the reaction medium also give rise to other tricarboxylic acids (eg, 1,3,5-tricarboxylbenzene). In addition, the increased presence of tricarboxylic acids in the reaction medium increases the amount of tetracarboxylic acid formation (eg, 1,2,4,5-tetracarboxybenzene). The control of the summed production of all the aromatic carboxylic acids having more than 2 carboxylic acid groups is a factor in the sizing of the preferred levels of meta-substituted and orthosubstituted species in the feed of the recycled solvent, in the feed of oxidizable compound, and in the reaction medium according to the present invention. For example, in the partial liquid phase oxidation of para-xylene to TPA, the inventors have discovered that the increased levels in the liquid phase of the reaction medium of several dissolved aromatic carboxylic acids lacking non-aromatic hydrocarbyl groups lead directly to the increased production of carbon monoxide and carbon dioxide. This increased production of carbon oxides represents a loss of production in both the oxidizer and the oxidizable compound, since Many of the later coproducted aromatic carboxylic acids, which on the one hand can be observed as impurities, on the other hand, also have commercial value. Thus, the appropriate removal of the relatively soluble carboxylic acids lacking non-aromatic hydrocarbyl groups of the recycled solvent has an economic value in preventing the production loss of the oxidizable aromatic compound and the oxidant, in addition to suppressing the generation of highly undesirable impurities. such as various fluorenones and trimellitic acid. For example, in the partial liquid phase oxidation of para-xylene to TPA, the inventors have discovered that the formation of 2, 5, '-tricarboxybiphenyl is apparently inevitable. 2, 5, '-tricarboxybiphenyl is an aromatic tricarboxylic acid formed by the coupling of two aromatic rings, perhaps by the coupling of dissolved para-substituted aromatic species with an aryl radical, perhaps an aryl radical formed by decarboxylation or decarbonylation of para-substituted aromatic species. Fortunately, 2, 5, 4 '-tricarboxybiphenyl typically occurs at lower levels than trimellitic acid and does not usually lead to significantly increased difficulties with the branching of polymer molecules during PET production. However, the inventors have discovered that elevated levels of 2,5,4'-tricarboxybiphenyl in a reaction medium comprising oxidation of alkyl aromatics according to preferred embodiments of the present invention leads to increased levels of highly colored and undesirable 2,6-DCF. Increased 2,6-DCF is possibly created from 2,5,4'-tricarboxybiphenyl by ring closure with loss of a water molecule, although the exact reaction mechanism is not known with certainty. If 2,5,4'-tricarboxybiphenyl, which is more soluble in solvent than acetic acid and water that is TPA, is allowed to accumulate very high within the recycled solvent, the conversion ratios to 2,6-DCF may reach be unacceptably large. For example, in the partial liquid phase oxidation of para-xylene to TPA, the inventors have discovered that aromatic carboxylic acids lacking non-aromatic hydrocarbyl groups (eg, isophthalic acid) generally lead to medium suppression of chemical activity of the reaction medium when present in the liquid phase in sufficient concentration. For example, in the partial liquid phase oxidation of para-xylene to TPA, the inventors have found that precipitation is often not ideal (ie without equilibrium) with respect to the relative concentrations of different chemical species in the solid phase and in the liquid phase. Perhaps, this is because the precipitation ratio is very fast at the preferred space-time reaction ratios in the present, which lead to non-ideal co-precipitation of impurities, to an occlusion, thus, when If you want to limit the concentration of certain impurities (eg, trimellitic acid and 2,6-DCF) within the raw TPA due to the configuration of the unit operations downstream, it is preferable to control their concentration in the solvent feed as well as their proportion of generation within the reaction medium. For example, the inventors have discovered that benzophorone compounds (e.g., 4,4'-dicarboxybenzophenone and 2,5,4'-tricarboxybenzophenone) made during the partial oxidation of para-xylene have undesirable effects on a reaction medium. of PET although benzophenone compounds are not as highly colored in TPA per se as fluorenone zones and anthraquinones. Accordingly, it is desirable to limit the presence of benzophenones and selected precursors in the recycled solvent and in the feed of the oxidizable compound. In addition, the inventors have discovered that the presence of high levels of benzoic acid, already admitted into the solvent recycled or formed within the reaction medium, leads to high production rates of 4,4'- dicarboxibenzophenone. In the review, the inventors have sufficiently discovered and quantified a surprising array of reactions for aromatic compounds lacking non-aromatic hydrocarbyl groups that are present in the partial liquid phase oxidation of para-xylene TPA. Recapitulation of only the case of benzoic acid only, the inventors have discovered that the increased levels of benzoic acid in the reaction medium of certain embodiments of the present invention leads to the greatly increased production of highly colored 9-fluorenone-2-carboxylic acid and undesirable, at greatly increased levels of 4,4' -dicarboxidibiphenyl, at increased levels of 4,4' -dicarxibenzophenone, at an average suppression of chemical activity of the proposed oxidation of para-xylene, and at increased levels of carbon monoxide and Concomitant yield losses. The inventors have discovered that the increased levels of benzoic acid in the reaction medium also lead to the increased production of isophthalic acid and phthalic acid, the levels of which are desirably controlled at low ranges according to the similar aspect of the current invention. The number and importance of reactions involving benzoic acid are perhaps even more surprising since some current inventors contemplate the use of acid benzoic instead of acetic acid as a primary solvent component (see, for example, U.S. Patent No. 6,562,997). Additionally, the present inventors have observed that benzoic acid is self-generated during the oxidation of para-xylene in proportions that are very important relative to its formation of impurities, such as toluene and ethylbenzene, commonly found in the oxidizable compound feed comprising -xylene of commercial purity. On the other hand, the inventors have discovered a small value of the additional regulation of the recycled solvent composition with respect to the presence of the oxidizable aromatic compound and with respect to the aromatic reaction intermediates that both retain the non-aromatic hydrocarbyl groups and are also relatively soluble in the recycled solvent. In general, these compounds are fed either to or are created within the reaction medium in proportions substantially larger than their presence in the recycled solvent; and the proportion of these compounds within the reaction medium is sufficiently large, they retain one or more of the non-aromatic hydrocarbyl groups, to appropriately limit their accumulation - within the recycled solvent. For example, during the partial oxidation of para-xylene in a medium of Multi-phase reaction, para-xylene is evaporated to a limited degree together with large amounts of solvent. When this evaporated solvent leaves the reactor as part of the discharge gas and condenses for recovery as a recycled solvent, a substantial evaporated para-xylene portion also condenses therein. It is not necessary to limit the concentration of this para-xylene in the recycled solvent. For example, if the solvent is separated from the solids in the suspension leaving an oxidation reaction medium of para-xylene, this recovered solvent will contain a similar concentration of dissolved paratoluic acid to that present at the removal point of the medium. reaction. Although it may be important to limit the permanent concentration of paratoluic acid within the liquid phase of the reaction medium, see below, it is not necessary to separately regulate the paratoluic acid in this portion of the recycled solvent because of its relatively good solubility and its flow rate. lower relative to the paratoluic acid pressure within the reaction medium. Similarly, the inventors have found little reason to limit the concentrations in the recycled solvent of the aromatic compounds with methyl substituents (eg toluic acids), aromatic aldehydes (eg, terephthalaldehyde), aromatic compounds with hydroxymethyl substituents ( for example, acid 4- hydroxymethylbenzoic acid), and brominated aromatics that retain at least one non-aromatic hydrocarbyl group (eg, alpha-bromo-para-toluic acid) immediately those found inherently in the liquid phase leaving the reaction medium that occurs in the oxidation xylene portion according to the preferred embodiments of the present invention. Surprisingly, the inventors have also discovered that it is also not necessary to regulate in the recycled solvent the concentration of intrinsically selected phenols produced during the partial oxidation of xylene, for these compounds are created and destroyed within the reaction medium in proportions much larger than its presence in the recycled solvent. For example the inventors have discovered that 4-hydroxybenzoic acid has relatively small effects on chemical activity in the preferred embodiments of the present invention when co-fed in proportions of above 2 grams of 4-hydroxybenzoic acid per one kilogram of -xylene, much higher than the natural presence in the recycled solvent, although it is reported by others, as a significant poison in the similar reaction medium (see, for example, W. Partenheimer, Catalysis Today 23 (1995) P. 81). Thus, there are numerous reactions and numerous considerations in establishing the preferred ranges of several aromatic impurities in the solvent feed as now disclosed. These findings are set forth in terms of average aggregate weight composition of all solvent streams that are fed into the reaction medium over the course of a set period of time, preferably one day, more preferably one hour, and most preferably one minute. . For example, if a solvent feed flows substantially continuously with a composition of 40 ppmw of isophthalic acid at a flow rate of 7 kilograms per minute, a second solvent feed flows substantially continuously with a composition of 2,000 ppmw of isophthalic acid at a flow rate of 10 kilograms per minute, and there are no other solvent feed streams entering the reaction medium, then the solvent composition is calculated (40 * 7 + 2,000 * 10) / (7 + 10 ) 0 = 1.193 ppmw of isophthalic acid. It is noteworthy that the weight of any oxidizable compound feed or of any oxidant feed that may be mixed with the feed of the solvent before they enter the reaction medium are not considered in the calculation of the average aggregate weight composition of the feeding. Table 1, next, lists preferred values for certain components in the solvent feed introduced into the reaction medium. The components of the solvent feed listed in Table 1 are as follows: 4-carboxybenzaldehyde (4-CBA),, 4'-dicarboxystilbene (4, '-DCS), 2,6-dicarboxyanthraquinone (2,6-DCA), 2,6-dicarboxyfluorenone (2,6-DCF), 2,7-dicarboxyfluorenone (2,7-DCF), 3, 5 -dicarboxifluorenone (3,5-DCF), 9-fluorenone-2-carboxylic acid (9F-2CA), 9-fluorenone-4-carboxylic acid (9F-4CA), total fluorenones that include other fluorenones not listed individually (total fluorenones), 4,4'-dicarboxbiphenyl (4,4 '-DCB), 2, 5, 4' -tribicarboxyphenyl (2, 5, '-TCB), phthalic acid (PA), isophthalic acid (IPA), benzoic acid (BA), trimellitic acid (TMA), 2,6-dicarboxibenzocoumarin (2,6-DCBC),, - dicarboxybenzyl (4,4'-DCBZ), 4,4'-dicarboxybenzophenone (4,4'-DCBP), 2,5,4'-tricarboxybenzophenone (2, 5, 4 '-TCBP), terephthalic acid (TPA), solids precipitates at 20 °, and total aromatic carboxylic acids lacking non-aromatic hydrocarbyl groups, Table 1, immediately provides the preferred amounts of these impurities in the CTA produced according to one embodiment of the present invention.

TABLE 1 - Components of the Solvent Feed Introduced in the Reaction Medium.

Many other aromatic impurities are also typically present in the recycled solvent, which generally vary in uniform levels and / or in proportion to one or more of the aromatic compounds disclosed. Methods for controlling the aromatic compounds disclosed in the preferred ranges will typically maintain other aromatic impurities at suitable levels. When bromine is used within the reaction medium, a large number of ionic and organic forms of bromine are known to exist in dynamic equilibrium. These various forms of bromine have different stability characteristics once they leave the reaction medium and pass through several unit operations belonging to the recycled solvent. For example, alpha-bromo-para-toluic acid may persist as such under some conditions or may be rapidly hydrolyzed under other conditions to form 4-hydroxymethylbenzoic acid and hydrogen bromine. In the present invention, it is preferable that at least about 40 weight percent, more preferable than at least about 60 weight percent, and far more preferable than at least about 80 weight percent of the total weight of the Bromine present in the solvent feed added to the reaction medium is in one or more of the following chemical forms: ionic bromine, alpha-bromo-para-toluic acid and bromoacetic acid.

Although the importance and value of the control of the aggregate average weight purity of the solvent feed within the desired ranges disclosed in the present invention have not been discovered and / or disclosed hitherto, adequate means to control the purity of the Solvent feed can be put together by several methods known in the art. First, any solvent evaporated from the reaction medium is typically of adequate purity which provides that liquid or solid from the reaction medium are not transported with the solvent evaporated. The feeding of the reflux solvent droplets in the uncoupling space of the discharge gas above the reaction medium as disclosed herein, appropriately limits such transportation; and the recycled solvent of suitable purity with respect to the aromatic compound can be condensed from such a discharge gas. Second, the most difficult and expensive purification of the blowing solvent feed is typically related to the solvent taken from the reaction medium in the liquid form and to the solvent which subsequently contacts the liquid and / or solid phase of the reaction medium withdrawn from the solvent. reaction vessel (eg, recycled solvent obtained from a filter in which the solids are concentrated and / or washed, recycled solvent obtained from a centrifuge and the solids are concentrated and / or washed, the solvent recycled taken from a crystallization operation, and so on). However, the means are also known in the art to effect the necessary purification of these recycled solvent streams using one or more previous descriptions. With respect to the control of precipitated solids in the recycled solvent that is within the specified ranges, suitable control means include, but are not limited to, gravimetric sedimentation, mechanical filtration using filter cloth over rotary band filters and rotary drum filters. , mechanical filtration using stationary filter media inside pressure vessels, hydrocyclones, and centrifuges. With respect to the control of dissolved aromatic species in the recycled solvent that is within the specified ranges, the control means includes, but is not limited to, those disclosed in U.S. Patent No. 4,939,297 and the U.S. patent application publication. No, 2005-0039288, incorporated herein by reference. However, none of these prior inventions discovered and disclosed the preferred levels of purity in the added solvent feed as disclosed herein. Rather, these prior inventions merely provide means for purifying selected and partial streams of the recycled solvent without deducting the present invention, optimal values of the composition of the weight average solvent feed added to the reaction medium. Turning now to the purity of the oxidizable compound feed, it is known that certain levels of isophthalic acid, phthalic acid, and benzoic acid are present and tolerable at low levels in purified TPA used for polymer production. On the other hand, it is known that these species are relatively more soluble in many solvents and can be removed advantageously from purified TPA by crystallization processes. However, from one embodiment of the invention disclosed herein, it is now known that the level control of several relatively soluble aromatic species, notably including isophthalic acid, phthalic acid, and benzoic acid, in the liquid phase of the medium of reaction is surprisingly important to control the level of polycyclic and colored aromatic compounds created in the reaction medium, to control compounds with more than 2 carboxylic acid functions per molecule, to control the reaction activity within the oxidation reaction medium partial, and to control the yield losses of the oxidant and the aromatic compound. It is known in the art that isophthalic acid, phthalic acid, and benzoic acid are formed in the reaction medium as follows. The impurity of feeding Meta-Xylene is oxidized in good with conversion and produces IPA. Orto-Xylene feed impurity oxidizes in good conversion and produces italic acid. The ethylbenzene and toluene feed impurities are oxidized in good conversion and produce benzoic acid. However, the inventors have observed that significant amounts of isophthalic acid, italic acid, and benzoic acid are also formed within a reaction medium comprising para-xylene by means other than the oxidation of meta-xylene, ortho-xylene, ethylbenzene and toluene . These other mtrinic chemical pathways possibly include decarbonylation, decarboxylation, the rearrangement of the transition state, and the addition of methyl and carbonyl radicals to aromatic rings. In the determination of preferred ranges of impurities in the oxidizable compound feed, many factors are relevant. Any impurity in the feed is likely to be a direct yield loss or a product purification cost and the purity requirements of the oxidized product are sufficiently stringent (for example, in a reaction medium for the partial oxidation of para-xylene, Toluene and ethylbenzene typically found in para-xylene of commercial purity leads to benzoic acid, and this benzoic acid is largely removed from most of the TPA commercial). When the partial oxidation product of a feed impurity participates in the additional reactions, factors other than the loss of simple yield and removal becomes appropriate when considering the cost of feed purification incurred (for example, in a reaction medium for partial oxidation or para-xylene, ethylbenzene conducts benzoic acid, and benzoic acid subsequently leads to highly colored 9-fluorenone-2-carboxylic acid, isophthalic acid, ophthalmic acid, and carbon oxides increased, among others). When the reaction medium generates additional amounts of an impurity by itself by means of chemical mechanisms not directly related to the feed impurities, the analysis becomes even more complex (for example, in a reaction medium for the partial oxidation of the -xylene, benzoic acid also self-generated from para-xylene by itself, furthermore, the downstream processing of the crude oxidation product can affect the considerations for the preferred feed purity, for example, the cost of removal to levels of a direct impurity (benzoic acid and subsequent impurities (isophyllic acid, phthalic acid, 9-fluorenone-2-carboxylic acid, and collaborators) may be one and the same, may be different from each other, and may be different from the requirements of removal of a largely unrelated impurity (for example, the incomplete oxidation product 4-CBA in the oxidation of para-xylene to TPA). The following feed purity ranges disclosed for para-xylene are preferred where the para-xylene is fed with the solvent and the oxidant to a reaction medium for partial oxidation to produce TPA. These ranges are more preferred in the TPA production process having post-oxidation steps to remove impurities from the reaction medium different from the oxidant and the solvent (for example catalyst metals).

These intervals are still more preferred in TPA production processes that remove additional 4-CBA from CTA (for example, by converting CTA to dimethylterephthalate plus impurity esters and subsequent separation of methyl 4-CBA ester by distillation, by oxidative digestion methods to convert 4-CBA to TPA, by hydrogenation methods to convert 4-CBA to para-toluic acid, which are then separated by partial crystallization methods.These intervals are much more preferred in TPA production processes that remove additional 4-CBA from CTA by oxidizing digestion methods to convert 4- CBA to TPA.The use of new knowledge of intervals Preferred aromatic recycling compounds and the relative amounts of the aromatic compounds formed directly from the oxidation of the feed impurities as compared to other intrinsic chemical routes, the improved ranges for the impurities that have been discovered for the impure para-xylene which is fed to a partial oxidation process for the production of TPA. Table 2 below provides preferred values for the amount of meta-xylene, ortho-xylene, and ethylbenzene + toluene in the para-xylene feed. Table 2 - Para-xylene Feeding Components Impure Those skilled in the art will now recognize that the above impurities within the para-xylene can have their greatest effect on the reaction medium after that their partial oxidation products have accumulated in the recycled solvent. For example, feeding the uppermost amount of the most preferred range of meta-xylene, 400 ppmw, will immediately produce approximately 200 ppmw of isophthalic acid within the liquid phase of the reaction medium when operating with about 33 weight percent of solids in the reaction medium. This is compared to an entry of the uppermost amounts of the most preferred range for isophthalic acid in the recycled solvent of 400 ppmw which, after taking into account a typical solvent evaporation to cool the reaction medium, amounts to approximately 1,200 of acid isophthalic within the liquid phase of the reaction medium. Thus, it is the accumulation of the partial oxidation products over time within the recirculated solvent that represents the largest probable impact of the impurities of meta-xylene, ortho-xylene, ethylbenzene and toluene in the feed of the impure para-xylene. Accordingly, the above ranges for the impurities in the feed of the impure para-xylene are preferred to be maintained by at least one half of each day of the operation of any partial oxidation reaction medium in a particular manufacturing unit, more preferably at least three quarters of each day for at least seven consecutive days of operation, and much more preferably when the averages heavy in more than the feed composition of the impure para-xylene is within the preferred ranges for at least 30 consecutive days of operation. The means for obtaining the impure para-xylene of preferred purity are already known in the art and include, but are not limited to, distillation, partial crystallization methods at sub-environmental temperatures, and molecular sieving methods using the size adsorption of selective pore. However, the preferred ranges of purity specified herein are, at their high end, more demand and expensive than characteristically practiced by commercial suppliers of para-xylene; and still at the low end, the preferred proportions avoid the excessively expensive purification of para-xylene to feed a partial oxidation reaction medium upon discovery and disclosure where the combined effects of self-generation of para-xylene impurity by itself and of the advisory reactions of impurities within the reaction medium become more important than the supply of impurities inside the impure para-xylene. When the feed stream containing xylene contains selected impurities, such as ethylbenzene and / or toluene, the oxidation of these impurities can generate benzoic acid. As used herein, the term "benzoic acid generated from impurities" will denote the acid benzoic derived from any source other than xylene during oxidation of xylene. As disclosed herein, a portion of benzoic acid produced during the oxidation of xylene is derived from xylene by itself. The benzoic acid production of xylene is distinctly in addition to any portion of benzoic acid production which may be benzoic acid generated from impurities. Unrelated by theory, it is believed that benzoic acid is derived from xylene within the reaction medium when several intermediate oxidation products of xylene spontaneously decarbonilate (loss of carbon monoxide) or decarboxylate (loss of carbon dioxide). ) to produce aryl radicals in this way. These aryl radicals can then be separated from a hydrogen atom from one of many available sources in the reaction medium and produce self-generated benzoic acid. Whatever the chemical mechanism, the term "self-generated benzoic acid", as used herein, will denote the benzoic acid derived from xylene during the oxidation of xylene. As also disclosed herein, when para-xylene is oxidized to produce terephthalic acid (TPA), the production of self-generated benzoic acid causes loss of para-xylene yield and loss of oxidant yield. In addition, the presence of benzoic acid Self-generated in the liquid phase of the reaction medium correlates with increases for many undesirable side reactions, notably including the generation of highly colored compounds called mono-carboxy-fluorenones. The self-generated benzoic acid also contributes to the undesirable accumulation of benzoic acid in the recycled filtrate which also raises the concentration of the benzoic acid in the liquid phase of the reaction medium. Thus, the formation of the self-generated benzoic acid is desirably minimized, but this is also appropriately considered simultaneously with the benzoic acid generated from impurities, with factors affecting the consumption of the benzoic acid, with characteristic factors of other reaction selectivity problems, and with full economy. The inventors have discovered that the self-generation of benzoic acid can be controlled for levels by the appropriate selection of, for example, temperature, xylene distribution, and oxygen availability within the reaction medium during oxidation. Without wishing to be related by theory, lower temperatures and improved oxygen availability seem to suppress decarbonylation and / or decarboxylation ratios, thus avoiding the appearance of loss of acid yield self-generated benzoic The availability of sufficient oxygen seems to direct the aryl radicals towards other more benign products, in particular hydroxybenzoic acids. The distribution of xylene in the reaction medium can also affect the balance between the conversion of the aryl radical to benzoic acid or hydroxybenzoic acid. Whatever the chemical mechanisms, the inventors have discovered the reaction conditions which, although quite mild to reduce the production of benzoic acid, are severe enough to oxidize a high fraction of the production of hydroxybenzoic acid to carbon monoxide and / or dioxide. carbon, which is easily removed from the oxidation product. In a preferred embodiment of the present invention, the oxidation reactor is configured and operated in such a way that the formation of self-generated benzoic acid is minimized and the oxidation of hydrobenzoic acids to carbon monoxide and / or carbon dioxide is maximized . When the oxidation reactor is used to oxidize para-xylene to terephthalic acid, it is preferred that the para-xylene constitutes at least about 50 weight percent of the total xylene in the feed stream introduced into the reactor. More preferably, the para-xylene constitutes at least about 75 percent by weight of the total xylene in the stream of feeding. Still more preferably, the para-xylene constitutes at least about 95 percent by weight of the total xylene in the feed stream. Much more preferably, para-xylene constitutes substantially all of the total xylene in the feed stream. When the reactor is used to oxidize the para-xylene to terephthalic acid, it is preferred that the production ratio of terephthalic acid be maximized, while the production rate of the self-generated benzoic acid is minimized. Preferably, the ratio of the production ratio (by weight) of terephthalic acid to the production ratio (by weight) of self-generated benzoic acid is at least about 500: 1, more preferably at least about 1,000: 1 and much more preferably at least 1,500: 1. As will be seen below, the production ratio of the self-generated benzoic acid is preferably measured when the concentration of benzoic acid in the liquid phase of the reaction medium is below 2,000 ppmw, more preferably below 1,000 ppmw and much more preferably below 500 ppmw , because these low concentrations suppress reactions of adequately low proportions that convert benzoic acid to other compounds. The combination of self-generated benzoic acid and benzoic acid generated by impurities, the ratio of production ratio (by weight) of terephthalic acid to the production ratio (by weight) of total benzoic acid is preferably at least about 402: 1, more preferably at least about 700: 1, and most preferably at least minus 1,100: 1 As will be seen below, the aggregate production ratio of the self-generated benzoic acid plus the benzoic acid generated by impurities is preferably measured when the concentration of benzoic acid in the liquid phase of the reaction medium is below 2,000 ppmw, more preferably below 1,000 ppmw , and much more preferably below 500 ppmw, because these low concentrations suppress reactions of adequately low proportions that convert benzoic acid to other compounds. As disclosed herein, high concentrations of benzoic acid in the liquid phase of the reaction medium leads to the increased formation of many other aromatic compounds, several of which are harmful impurities in the TPA; and, as disclosed herein, high concentrations of benzoic acid in the liquid phase of the reaction medium leads to increased formation of carbon oxide gases, the formation of which represents the loss of yield on the oxidant and on the compounds aromatics and / or the solvent. Furthermore, it is now disclosed that the inventors have discovered a portion considerable of this increased information of other aromatic compounds and carbon oxides derived from reactions that convert some of the benzoic acid molecules by themselves, as is contrasted to the benzoic acid that catalyzes other reactions and that is consumed by itself. Accordingly, the "net generation of benzoic acid" is defined herein as the time-averaged weight of all the benzoic acid leaving the reaction medium minus the time-averaged weight of all of the benzoic acid entering the medium. reaction during the same period of time. This net generation of benzoic acid is often positive, driven by the proportions of benzoic acid formation generated by impurities and self-generated benzoic acid. However, the inventors have discovered that the conversion ratio of benzoic acid to benzoic acid to carbon oxides, and to several other compounds, appears to increase approximately linearly as the concentration of benzoic acid increases in the liquid phase of the reaction medium. , measured when other reaction conditions comprising temperature, oxygen availability, STR, and reaction activity are kept approximately constant. Thus, when the concentration of benzoic acid in the liquid phase of the reaction medium is sufficiently large, perhaps due to a high concentration of the acid The conversion of bic acid molecules to other compounds, including carbon oxides, may be equal to or greater than the chemical generation of the new bic acid molecules. In this case, the net generation of bic acid can be balanced near zero or even negative. The inventors have found that when the net generation of bic acid is positive, then the ratio of the production ratio (by weight) of terephthalic acid in the reaction medium compared to the ratio of net generation of bic acid to the reaction medium is preferably above 700: 1, more preferably above about 1,100: 1, and much more preferably above 4,000: 1 .. The inventors have found that when the net generation of bic acid is negative, the ratio of the proportion of production (by weight) of terephthalic acid in the reaction medium compared to the net generation rate of bic acid in the reaction medium is preferably above about 200: (-1), more preferably above about 1.00: ( -1), and much more preferably above 5,000: (-1). The inventors have also discovered preferred ranges for the composition of the suspension (liquid + solid) removed from the reaction medium and for the solid CTA portion of the suspension. The preferred suspension and Preferred CTA compositions are surprisingly superior and useful. For example, the purified TPA produced from this preferred CTA by oxidative digestion has a sufficiently high level of total impurities and colored impurities such that the purified TPA is suitable, without the hydrogenation of additional -CBA and / or colored impurities, for a wide range of applications in PET fibers and EPT packaging applications. For example, the preferred suspension composition provides a liquid phase of the reaction medium that is relatively low in concentration of important impurities and these significantly reduce the creation of other, even more undesirable, impurities as disclosed herein. In addition, the preferred suspension composition importantly aids the subsequent processing of liquid from the suspension to become the appropriately pure recycled solvent, according to other embodiments of the present invention. The CTA produced according to one embodiment of the present invention contains less impurities of the selected types than the CTA produces by conventional processes and apparatuses, notably or those employing recycled solvent. Impurities that may be present in the CTA include the following. 4-carboxybldehyde (4-CBA), 4,4'-dica rboxi s til beno (4,40-DCS), 2,6-dica rbox ant raquinone (2,6- DCA), 2,6-dicarboxylorenone (2,6-DCF), 2,7-dicarboxy luorenone (X7-DCF), 3,5-dicarboxy fluorenone (3,5-DCF), 9-fluorenone-2-acid carboxylic (9F-2CA), 9-fluorenone-4-carboxylic acid (9F-4C?), A, A '-dicarboxi bi phenyl (4,' -DCB), 2, 5, 4'-tricarboxybiphenyl (2, 5) , '--TCB), italic acid (PA), isophthalic acid (IPA), bic acid (BA), trimellitic acid (TMA), para-toluic acid (PTAC), 2,6-dicarboxibcoumarin (2,6-DCBC) ), 4,4 'dicarboxybl (4,4'-DCBZ), 4,4' -dicarboxibphenone (4,4'-DCBP), 2,5,4'-tricarboxybphenone (2, 5, 4' -TCBP). Table 3, below, provides the preferred amounts of these impurities in CTA produced according to one embodiment of the present invention. TABLE 3 - Impurities of CTA Furthermore, it is preferred that the CTA produced according to one embodiment of the present invention have reduced color content relative to the CTA produced by conventional processes and apparatuses, notably those employing recycled solvent. Thus, it is preferred that the CTA produced according to one embodiment of the present invention have a percent percent transmission at 340 nanometers (nm) of at least about 25 percent, more preferably at least about 50 percent, and most preferably at least 60 percent. It is further preferred that the CTA produced according to one embodiment of the present invention have a percent percent transmission at 400 nanometers (nm) of at least about 88 percent, more preferably at least about 90 percent, and much more preferably at least 92 percent. The test for the percent transmittance provides a measurement of the light adsorbent impurities, colored, present from the PTA or CTA. As used in the present, the test refers to measurements made on a portion of a solution prepared by dissolving 2.00 grams of TPA or dry solid CTA in 20.0 milliliters of dimethylsulfoxide (DMSO), analytical grade or better. A portion of this solution is then placed in a semi-micro flow cell Hellrna, PN 176.700, which is made of quartz and has a light path of 1.0 cm and a volume of 0.39 milliliters.

(Hellma USA, 80 Skylme Drive, Plainview, NY 11803). An Agilent 8453 Diode Array spectrophotometer is used to measure the transmission of different wavelengths of light through this filled-flow cell. (Agilent Technologies, 395 Page Mili Road, Palo Alto, CA 94303). After the appropriate correction for the absorbance of the background, including but not limited to the cell and the solvent used, the results of percent transmittance, which characterize the fraction of incident light that is transmitted through the solution, it is reported directly by the machine. The percent transmission values at light wavelengths of 340 nanometers and 400 nanometers are particularly useful for discrimination of pure TPA from many of the impurities typically found therein. The preferred ranges of various aromatic impurities in the suspension phase (solid -f- liquid) of the reaction medium are given below in Table 4.

TABLE 4 - Impurities of the Suspension These preferred compositions for the suspension encompass the preferred composition of the liquid phase of the reaction medium while usefully avoiding Experimental difficulties pertaining to the precipitation of the additional liquid phase components of the reaction medium in the solid phase components during the sampling of the reaction medium, the separation of liquids and solids, and the change of the analytical conditions. Many other aromatic impurities are also typically present in the suspension phase of the reaction medium and the CTA of the reaction medium, which generally vary in even lower levels and / or in proportion to one or more of the aromatic compounds disclosed. The control of the aromatic compounds disclosed in the preferred ranges will maintain other aromatic impurities at suitable levels. These advantageous compositions for the phase suspended in the reaction medium and for the solid CTA taken directly from the suspension are allowed when operating with embodiments of the invention disclosed herein for the partial oxidation of para-xylene to TPA. The measurement of the concentration, of the low level components in the solvent, the recycled solvent, CTA, suspension of the reaction medium, and the PTA are formed using liquid chromatography methods. Two interchangeable modalities are now described. The method referred to herein as HPLC-DAD comprises high pressure liquid chromatography (HPLC) coupled with a diode array detector (DAD) for provide the separation and quantification of several molecular species within a ciada sample. The instrument used in this measurement is a 12100 HPLC model equipped with a DAD, provided by Agilent Technologies (Palo Alto, CA), although other suitable instruments are also commercially available and from other suppliers. As is known in the art, both the elution time and the detector response are calibrated using known compounds present in known amounts, compounds and amounts that are appropriate for those occurring in current unknown samples. The method referred to herein as HPLC-MS comprises high pressure liquid chromatography (HPLC) coupled with mass spectrometry (MS) to provide separation, identification, and quantification. determination of several molecular species within a given species. The instruments used in this measurement is an HPLC Alliance and ZQ MS provided by Waters Corp. (Milford, MA), although other suitable instruments are also commercially available and from other suppliers. As is known in the art, both the elution time and the mass spectrometric response are calibrated using known compounds present in known amounts, compounds and amounts that are appropriate for those occurring in the current unknown samples.

Another embodiment of the present invention relates to the partial oxidation of the aromatic oxidizable compound with the appropriate residue of the suspension of the impurities, the appropriate residue of the suspension of the harmful aromatic impurities on the one hand against the production of carbon dioxide and monoxide. carbon, collectively (COx), in the other part. These carbon oxides typically are salts of the reaction vessel in the discharge gas, and correspond to a destructive loss of the solvent and oxidizable compound, which include the finally preferred oxidized derivatives (eg, acetic acid, para-xylene and TPA). The inventors have discovered lower linkages for the production of carbon oxides below which it appears that the high creation of harmful aromatic impurities, as described below, and the low complete conversion level are inevitably very deficient to be of economic use. The inventors have also discovered superior bonds of carbon oxides above which the generation of carbon oxides continues to increase with little additional value provided by the reduction in the generation of noxious aromatic impurities. The inventors have discovered that the reduction of the liquid phase concentrations of the aromatic oxidizable compound feed and of the intermediate aromatic species within a reaction medium leads to lower generation ratios for harmful impurities during the partial oxidation of the oxidizable aromatic compound. These harmful impurities include coupled aromatic rings and / or aromatic molecules that contain more than the desired number of carboxylic acid groups (for example, in the oxidation of para-xylene of harmful impurities include 2,6-dicarboxyanthraquinone, 2,6-dicarboxy Luorenone, trimellitic acid, 2,5,4'-tricarboxybiphenyl, and 2, 5, 4 '-benzophenone). Aromatic intermediate species include aromatic compounds descended from the feed of the oxidizable aromatic compound and still retaining non-aromatic hydrocarbyl groups (for example, in the oxidation of para-xylene the intermediate aromatic species comprise para-tolualdehyde, teref taldehyde, acid for tolu Ico, 4-CBA, 4-hydroxymethylbenzoic acid, and alpha-bromo-para-tolui acid co). The feeding of the aromatic oxidizable compound and the intermediate aromatic species which retain non-aromatic hydrocarbyl groups, when present in the liquid phase of the reaction medium, appear to lead to harmful impurities in a manner similar to those already disclosed in the present for the species dissolved aromatics lacking non-aromatic hydrocarbyl groups (eg, isophthalic acid). The adjustment against this need for activity of higher reaction to suppress the formation of noxious aromatic impurities during the partial oxidation of the oxidizable aromatic compound, the inventors have discovered that the undesirable concomitant result is the increased production of carbon oxides. It is important to appreciate that these carbon oxides represent a loss of yield of the oxidizable compound and the oxidant, not just the solvent. Explicitly, a substantial and sometimes major fraction of the carbon oxides come from the oxidizable compound, and its derivatives, before the solvent; and often the oxidizable compound costs more per unit of carbon than the solvent. Furthermore, it is important to appreciate that the desired carboxylic acid product (eg, TPA) is also subject to over oxidation to the carbon oxides when present in the liquid phase of the reaction medium. It is also important to appreciate that the present invention relates to reactions in the liquid phase of the reaction medium and to the concentrations of reagents therein. This is in contrast to some previous inventions that relate directly to the creation in the precipitated solid form of the aromatic compound that retains non-aromatic hydrocarbyl groups. Specifically, for the partial oxidation of para-xylene to TPA, certain previous inventions correspond to the amount of 4-CBA precipitated in the solid phase of the CTA. However, the present inventors have discovered a variation of greater than two to one for the ratio of 4-CBA in the solid phase to 4-CBA in the liquid phase, using the same specifications of temperature, pressure, catalysis, solvent composition and para-xylene space-time reaction ratio depending on whether the partial oxidation is conducted in a key car or in a reaction medium with the formation of oxygen and para-xylene steps according to the present invention. Furthermore, the inventors have observed that the ratio of 4-CBA in the solid phase to 4-CBA in the liquid phase can also vary by more than two to one in either well-mixed reaction medium or in steps depending on the proportion of space-time reaction of para-xylene and otherwise similar specifications of temperature, pressure, catalysis, and solvent composition. Additionally, 4-CBA in the solid phase CTA does not appear to contribute to the formation of harmful impurities, and the 4-CBA in the solid phase can be recovered and oxidized on the TPA simply and in high yield (for example by digestion oxidant of the CTA suspension as described herein); while the removal of harmful impurities is much more difficult and expensive than the removal of solid phase 4-CBA, and the production of carbon oxides represents a permanent loss of performance. So, it's important distinguish that this aspect of the present invention relates to compositions in liquid phase in the reaction medium. Whether the source of the solvent or the oxidizable compound, the invention has discovered that in the conversions of commercial utility the production of carbon oxides is strongly related to the level of the complete reaction activity despite the wide variation in the specific combination of temperature, metals, halogen, temperature, acidity of the reaction medium as measured by the pH, concentration of water used to obtain the level of complete reaction activity. The inventors have found it useful for the partial oxidation of xylene to evaluate the level of the complete reaction activity using the liquid phase concentration of the toluic acids at half the height of the reaction medium, the bottom of the reaction medium, and the upper part of the reaction medium. Thus, an important simultaneous balance arises to minimize the creation of harmful impurities by increasing the reaction activity and still minimize the operation of the carbon oxides by decreasing the reaction activity. That is, if the complete production of carbon oxides is suppressed so low, then excessive levels of harmful impurities are formed, and vice versa. In addition, the inventors have discovered that the The solubility and relative reactivity of the desired carboxylic acid (eg, TPA) and the presence of other dissolved aromatic species lack non-aromatic hydrocarbyl groups a very important fulcrum in this balance of carbon oxides against harmful impurities. The carboxylic acid of the desired product typically dissolves in the liquid phase of the reaction medium, although it is also present in solid form. For example, at temperatures in the preferred ranges. The TPA is soluble in a reaction medium comprising acetic acid and water at levels ranging from about 1,000 ppmw to over 1 percent by weight, with the solubility increasing as the temperature increases. However, there are differences in reaction rates towards the formation of various harmful impurities in the feed of the oxidizable aromatic compound (for example, para-xylene, aromatic reaction intermediates (for example para-toluic acid), carboxylic acid of the desired product (for example TPA), and of the aromatic species lacking the non-aromatic hydrocarbyl groups (for example isophthalic acid), the presence and reactivity of the two subsequent groups establish a region of decreasing returns with respect to the additional suppression of the first two groups, the feeding of the oxidizable aromatic compound and the aromatic reaction intermediates, for example, in a partial oxidation of para-xylene to TPA, if the TPA dissolves is 7,000 ppmw in the liquid phase of the reaction medium under given conditions, the dissolved benzoic acid amounts to 8,000 ppmw the dissolved isophthalic acid amounts to 6,000 ppmw and the italic acid When dissolved, it rises to 2.00 ppmw, then the value towards the additional decrease of the total harmful compounds begins to decrease as the reaction activity increases to suppress the liquid phase concentration of the para-toluic acid and the A-CBA below levels. Similar. That is, the presence and concentration in the liquid phase in the reaction medium of the aromatic species lacking non-aromatic hydrocarbyl groups is altered very little by increasing the reaction activity, and their presence serves to expand towards the region of the returns reducing agents to reduce the concentration of the reaction intermediates in order to suppress the formation of harmful impurities. Thus, one embodiment of the present invention provides preferred ranges of carbon oxides, bonded on the lower end by the low reaction activity and the excessive formation of harmful impurities and on the upper end by excessive carbon losses, but at higher levels. lower than those previously discovered and described as commercially useful. Therefore, the formation of carbon oxides preferably they are controlled co or follow. The ratio of moles of the total carbon oxides produced to moles of the oxidizable aromatic compound feed is preferably greater than about 0.02: 1, more preferably greater than about 0.04: 1, still more preferably greater than about 0.05: 1, and much more preferably greater than 0.06: 1. At the same time, the ratio of moles of the total carbon oxides produced to moles of the feed of the oxidizable aromatic compound is preferably less than about 0.24: 1, more preferably less than about 0.22: 1, still more preferably less than about 0.19: 1, and much more preferably less than 0.15: 1. The ratio of moles of carbon dioxide produced to moles of the oxidizable aromatic compound feed is preferably greater than about 0.01: 1, more preferably greater than about 0.03: 1, still more preferably greater than about 0.04: 1, and much more preferably greater than 0.05: 1. At the same time, the ratio of moles of carbon dioxide produced to moles of the oxidizable aromatic compound feed is preferably less than about 0.21: 1, more preferably less than about 0.19: 1, still more preferably less than about 0.16: 1, and much more preferably less than 0.11: 1. The ratio of moles of carbon monoxide produced to moles of the oxidizable aromatic compound feed is preferably greater than about 0.005: 1, more preferably greater than about 0.010: 1, still more preferably greater than about 0.015: 1, and much more preferably greater than 0.020: 1. At the same time, the ratio of moles of the carbon monoxide produced to moles of the oxidizable aromatic compound feed is preferably less than about 0.09: 1, more preferably less than about 0.07: 1, still more preferably less than about 0.05: 1, and much more preferably less than 0.04: 1. The carbon dioxide content in the dry discharge gas of the oxidation reactor is preferably greater than about 0.10 mole percent, more preferably greater than about 0.20 mole percent, still more preferably greater than about 0.25 mole percent, and much more preferably greater than 0.030 mol percent. At the same time, the carbon dioxide content in the dry discharge gas of the oxidation reactor is preferably less than about 1.5 mole percent, more preferably less than about 1.2 mole percent, still more preferably less than about 0.9 percent. percent in mol, and much more preferably less than 0.8 percent in mol. The content of the carbon monoxide in the dry discharge gas of the oxidation reactor is preferably greater than about 0.5 mole percent, more preferably greater than about 0.10 mole percent, still more preferably greater than about 0.15 mole percent, and much more preferably greater than 0.18 mole percent. At the same time, the carbon monoxide content in the dry discharge gas of the oxidation reactor is preferably less than about 0.60 mole percent, more preferably less than about 0.50 mole percent, still more preferably less than about 0.35 mole percent. one hundred mole, and much more preferably less than 0.28 mole percent. The inventors have discovered that an important factor in reducing the production of carbon oxides at these preferred ranges is to improve the purity of the recycled filtrate and the feed of the oxidizable compound to reduce the concentration of aromatic compounds lacking non-aromatic hydrocarbyl groups in accordance to the descriptions of the present invention - this simultaneously reduces the formation of carbon oxides and harmful impurities. Another factor is to improve the distribution of the para-xylene and the oxidant within the reaction vessel according to the descriptions of the present invention.

Other tactors that allow the above preferred levels of the carbon oxides are to operate with the gradients in the reaction medium as disclosed herein for pressure, for temperature, for concentration of the oxidizable compound in the liquid phase, and for the oxidant. in the gas phase. Other factors that allow the above preferred levels of carbon oxides are to operate within the preferred descriptions herein for the space-time reaction ratio, pressure, temperature, solvent composition, catalyst composition, and mechanical geometry of the reaction. An important benefit of the operation within the preferred ranges of carbon oxide formation is that the use of molecular oxygen can be reduced, although not at stoichiometric values. Notwithstanding the formation of good caps of the oxidant and the oxidizable compound according to the present invention, an excess of oxygen must be retained above the stoichiometric value, as calculated for feeding the oxidizable compound alone, to take into account some losses of oxygen. carbon oxide and provide the excess molecular oxygen to control the formation of harmful impurities. Specifically for the case where the xylene is the feed of the oxidizable compound, the feed ratio of the weight of the molecular oxygen to the weight of the xylene is preferably greater than about 0. 91: 1.00, more preferably greater than about 0.95: 1.00, and much more preferably greater than 0.99: 1.00. At the same time, the feed ratio of the weight of the molecular oxygen to the weight of the xylene is preferably less than about 1.20: 1.00, more preferably less than about 1.12: 1.00, and much more preferably less than 1.06: 1.00. Specifically for the xylene feed, the time-averaged content of the molecular oxygen in the dry discharge gas of the oxidation reactor is preferably greater than about 0.1 mol, more preferably greater than about 1 mol percent, and much more preferably higher that 1.5 percent in mol. At the same time, the time-averaged content of the molecular oxygen in the dry discharge gas of the oxidation reactor is preferably less than about 6 mole percent, more preferably less than about 4 mole percent, and much more preferably less than 3 percent in mol. Another important benefit of the operation within the preferred ranges of carbon oxide formation is that less of the aromatic compound is converted to carbon oxides and other less valuable forms. This benefit is evaluated using the sum of the moles of all the aromatics leaving the reaction medium divided by the sum of the moles of all the compounds aromatics entering the reaction medium during a continuous period of tempo, preferably 1 hour, more preferably 1 day, and much more preferably 30 consecutive days. This ratio is then referred to herein as the "molar survival ratio" for the aromatic compounds through the reaction medium and is expressed as a numerical percentage. If all the incoming aromatic compounds that come out of the reaction medium as aromatics, but mainly in oxidized forms of the incoming aromatic compounds, then the molar survival ratio has its maximum value of 100 percent. If exactly one out of every hundred incoming aromatic molecules is converted to carbon oxides and / or other non-aromatic molecules (eg acetic acid) while passing through the reaction medium, then the molar survival ratio is 99 percent. Specifically for the case where xylene is the main feed of the oxidizable aromatic compound, the molar survival ratio for the aromatic compounds through the reaction medium is preferably greater than about 98 percent, more preferably greater than about 98.5 percent, and much more preferably less than 99.0 percent. At the same time and in order for the reaction activity to complete enough, the molar survival ratio for the aromatic compounds through the medium of The reaction is preferably less than about 99.9 percent, more preferably less than about 99.8 percent, and much more preferably less than about 99.7 percent when xylene is the main feed of the oxidizable aromatic compound. Another aspect of the present invention involves the production of methyl acetate in a reaction medium comprising acetic acid and one or more of the oxidizable aromatic compounds. This methyl acetate is relatively volatile compared to water and acetic acid and thus tends to follow the discharge gas unless additional cooling or other unit operations are employed to recover it and / or to destroy it before it releases the discharge gas. back to the environment. The formation of methyl acetate thus represents an operating cost and also a cost of capital. Perhaps methyl acetate is formed by first combining a methyl radical, perhaps from the decomposition of acetic acid with oxygen to produce methyl hydroperoxide, by subsequently breaking down to form methanol and by finally reacting the methanol produced with acetic acid remaining to form methyl acetate. Whatever the chemical route, the inventors have found that every time the production of methyl acetate is so low that a proportion, then the production of carbon oxides is also so low and the production of the harmful aromatic impurities are so high. If the production of methyl acetate is in such a high proportion, then the production of carbon oxides is also unnecessarily high which leads to yield losses of the solvent, the oxidizable compound and the oxidant. When employing the preferred embodiments disclosed herein, the production ratio of the moles of the methyl acetate produced to moles of the oxidizable aromatic compound feed is preferably greater than about 0.005: 1, more preferably greater than about 0.010: 1. , and much more preferably greater than 0.020: 1. At the same time, the production ratio of moles of the methyl acetate produced to moles of the oxidizable aromatic compound feed is preferably less than about 0.09: 1, more preferably less than about 0.07: 1, still more preferably less than about 0.05: 1, and much more preferably less than 0.04: 1. Certain embodiments of this invention may be further illustrated by the following examples, although it should be understood that these examples are included merely for purposes of illustration and are not intended to limit the scope of the invention unless otherwise specifically indicated. EXAMPLES 1-10 Example 1 is a calculated example of a bubble column oxidation reactor for the oxidation of para-xylene in a liquid phase of a three phase reaction medium. The bubble column reactor of Example 1 represents a proven industrial design with a para-xylene feed rate of 7,000 kilograms per hour. Examples 2 to 10 are calculated examples for bubble column oxidation reactors having operating capacities 7 times larger than the reactor of Example 1. F1G. 59 provides a table summarizing the different parameters of the bubble column oxidation reactor which are varied in Examples 1-10. EXAMPLE 1 This example employs a bubble column reaction vessel having a cylindrical, vertical section with an inner diameter that equals 2:44 meters. The height of the cylindrical section is 32 meters from the lower tangent line (TL) to the upper TL of the cylindrical section. The container fits with 2: 1 elliptical heads on the top and bottom of the cylindrical section. The height from the bottom of the reaction medium to the top to the cylindrical section is approximately 32.6 meters, and the total height of the reaction vessel is approximately 33.2 meters. The level of operation is approximately 25.6 meters above the bottom of the middle of reaction . The para-xylene is fed to the reactor at a permanent rate of 7,000 kilograms per hour. A filter solvent comprising mainly acetic acid is intimately mixed with the para-xylene in a permanent proportion of 70,000 kilograms per hour. The feed is distributed within the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using a horizontal distributor assembly designed to provide a substantially uniform release of the feed over the cross-sectional area that is located within the a radius of 0.45 * (inner diameter). The concentration of the catalyst components in the filter solvent is such that the composition within the liquid phase of the reaction medium is 1,800 ppmw of cobalt, 1,800 ppmw of bromine, and 100 ppmw of manganese. A separate stream of the reflux solvent is fed as droplets in the gas decoupling zone above the operation level of the reaction medium in a steady state of 49,000 kilograms per hour and is distributed over essentially the entire cross-sectional area of the zone of decoupling. This reflux solvent is without significant levels of the catalyst component. The combined water content of the filter solvent feed and the feed of the reflux solvent is such that the concentration of water within the liquid phase of the reaction medium is 6% by weight. The air feed rate is permanent at a rate of 35,000 kilograms per hour through an oxidant inlet distributor similar to that shown in FIGS. 12-15, and all the oxidant admission holes are located below the lower TL of the cylindrical section. The operating pressure of the gas from the top of the reaction vessel is permanently 0.52 megapascal gauge. The reaction vessel is operated in a substantially adiabatic manner so that the heat of the reaction raises the temperature of the incoming feeds and evaporates much of the incoming solvent. The measurement near the average elevation of the reaction medium, the operating temperature is about 160 ° C. The reaction medium comprising crude terephthalic acid (CTA) is removed from the side of the reaction vessel at an elevation of 15 meters in a permanent proportion using an external deaeration vessel. The relation L: D is 13.4 and the relation H: W is 10.5.

The volume occupied by the reaction medium is approximately 118 cubic meters, and the reaction vessel contains approximately 58,000 kilograms of suspension. The ratio of the suspension mass to the feed ratio of para-xylene is approximately 8. 3 hours. The reaction intensity of the space time is approximately 50 kilograms of para-xylene feed per cubic meter of the reaction medium per hour. The pressure differential of the bottom of the reaction medium to the discharge gas of the top part leaving the reaction vessel is about 0.12 megapascal. The surface velocity of the gas phase at the average height of reaction medium 3 is approximately 0.8 meters per second. The vertical surface area in contact with the reaction medium is approximately 197 square meters, which is approximately 3.16 '* Wmin * H. the ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 0.60 meters. Under the conditions of Example 1, the decomposition of acetic acid in the amounts of the reaction medium to approximately 0.03 kilograms per kilogram of the CTA produced is estimated. This is a significant cost in the total production economy. Useful indicators of the side-to-side flow rates within the bubble column vessel are the maximum averaged upward velocities of the suspension and the oxidant phase. In a cylindrical bubble column reaction vessel, these maximum upward velocities occur near the vertical axis of the symmetry of the cylindrical section. Calculated by a method derived from the Gas-Liquid Reciulation Gupta model (reference Churn-t? rbulent bubble columns; experiments and modeling; Gupta Puneet; Washington Univ., St. Louis, MO, USA.) Avail. UMI, Order No. DA3065044 (2002), 357 pp. From: Diss. Abstr int., B 20032, 63 (9) Dissertation written in English CAN 140: 130325 AN 2003: 424187 CAPLUS) and using a patented database, the velocity towards averaged over maximum time of the gas phase near the average elevation of the reaction medium is approximately 3.1 meters per second. Similarly calculated, the maximum upward speed, averaged in time of the suspension near the average elevation of the reaction medium is approximately 1.4 meters per second. Another useful indicator of side-to-side flow expense within the bubble column reaction vessel is the downward speed averaged over the maximum time of the suspension in the reaction vessel parts located away from the central core. In a cylindrical reaction vessel, this maximum downward velocity typically occurs in the region lying outside a radius of 0.35 * (internal diameter) of the vertical axis of symmetry of the cylindrical section. Calculated by a method derived from the Gas-Liquid Recirculation of Gupta model and using a proprietary database, the downward speed averaged over the maximum time of the suspension in The outer ring near the average elevation of the reaction medium is approximately 1.4 meters per second. EXAMPLE 2 In this example, the bubble column reactor is fed para-xylene at an increased rate of 49,000 kilograms per hour - 7 times higher in Example 1. Surface gas velocity, often considered an increased scale variable important for the bubble columns remains approximately the same as example 1 by increasing the section area of the reaction vessel to be approximately 7 times larger than in example 1. The ratios H: W and L: D, often considered variables of Important scale for the bubble columns is also kept approximately equal to Example 1. The other feed streams are increased with the same ratio of 7: 1 to Example 1 the feed compositions are the same as in Example 1, providing the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in Example 1. The operating pressure of the gas from the top of the reaction vessel is again 0.52 megapascal gauge, and the operating temperature is again approximately 160 ° C measured near the average rise of the reaction medium. The means of reaction comprising CTA is removed from the reaction vessel side at an elevation of 40 meters in a permanent ratio using an external deaeration vessel. The bubble column reaction vessel comprises a vertical cylindrical section with an inside diameter of 6.46 meters. The ratio L: D remains the same with example 1, and the height of the bottom of the reaction medium at the top of the cylindrical section is 86.3 meters. The top and bottom of the cylindrical section is adjusted with 2: 1 elliptical heads, the total height of the reaction vessel is very high, approximately 88.0 meters. The feed is distributed into the reaction vessel near a 2-mer elevation above the bottom of the reaction medium using a horizontal manifold assembly designed for a release over the cross-sectional area lying within a radius of 0.45 * (diameter internal). The air feed is again through an oxidant inlet distributor similar to that shown in FIGS 12-15, and all of the holes in the oxidant intake holes are located below the lower TL of the cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the decoupling zone. The H: W ratio of the reaction medium is maintained approximately equal to Example 1, and thus the level of operation is approximately 67.8 meters of the reaction medium. This leaves a decoupling height of approximately 18.5 meters in the cylindrical section plus approximately 1.6 meters in the upper part of the elliptical head. This decoupling height is excessive by approximately 10 meters. Thus, the escalation of the container with the constant L: D produces a mechanical installation that is excessively expensive for the capital (for example, excessive costs for the pressure vessel, for the foundations due to the mass and load of the wind, for the steel structural, for the process pipe and used, and / or for the wiring of instruments and electrical). The volume occupied by the reaction medium is approximately 2,200 cubic meters, and the reaction vessel contains approximately 1,100,000 kilograms of suspension. The ratio of the suspension mass to the para-xylene feed ratio is approximately 22 hours, greatly increased to Example 1. The space-time reaction intensity is only about 22 kilograms of para-xylene feed per cubic meter of the feed. hourly reaction medium, greatly reduced compared to example 1. The pressure differential of the bottom of the reaction medium to the discharge gas of the top part leaving the reaction vessel rises approximately 0.33 megapascal, greatly increased compared to Example 1. The vertical surface area in contact with the reaction medium is approximately 1,393 square meters which is approximately 3.18 * Wmin * H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.58 meters, greatly compared to Example 1. Thus, scaling the dimensions of the reaction medium to maintain both the surface velocity and the ratio H: W as approximately constant between this Example and Example 1 has produced changes in the reaction conditions. In the rest, these changes are highly unfavorable. There are positive effects in this Example (for example more oxidizable compound dilution concentrations, lower demand on the ratio of mass transfer per unit volume for molecular oxygen from the gas phase to the liquid phase, and so on) leading to the production of few colored, undesirable byproducts per unit CTA. However, there are several economic penalties that relate to the decomposition of acetic acid and the pressure and energy required to supply air to the bottom of the bubbling volume reaction vessel. The decomposition of acetic acid is approximately proportional to the mass of the acetic acid in the reaction medium, each time the operating temperature and the composition of the liquid phase remain approximately constant and when the para-xylene is fed with an excess of molecular oxygen. Because the much larger mass of acetic acid in the reaction vessel compared to the amount of CTA produced in this example, it is estimated that the decomposition of acetic acid is raised approximately 0.09 kilograms per kilogram of CTA produced. In addition, the air compressor must supply air in reaction medium with a pressure that is 0.85 megapascal gauge in this example, while the pressure delivered is 0.64 megapascal gauge in Example 1. For an air supply ratio of 245,000 kilograms per hour and with typical indulgence for various understanding and supply efficiencies, the additional energy requirement for the highest supply pressure in this Example is approximately 3,000 kilowatts, continuously. Thus, the scale reduction of the reaction medium of this example with the approximately constant superficial gas velocity and the H: W ratio provide unacceptable economy, despite the good quality of the expected CTA. EXAMPLE 3 This example scales the process of Example 1 using surface velocity and intensity of space-time reaction. This leads to poor product quality because, in simple terms, natural convection flow patterns inherently produce a vertically deficient reaction profile. In this example, the feed rate of para-xylene is again 49,000 kilograms per hour - 7 times higher than in Example 1. The velocity of the surface gas is again maintained approximately to Example 1, but the ratios L: D and H: W do not stay the same. In contrast, the STR remains approximately equal to Example 1. It provides a column base pressure and an acetic acid decomposition ratio that are approximately equal to Example 1. The other feed streams increase with the same ratio 7: 1 to Example 1. The compositions of the feeds are the same as in Example 1, which provide the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in the Example. The operating pressure of the gas from the top of the reaction vessel is again 0.52 megapascal gauge, and the operating temperature is again approximately 160 ° C measured about the average rise of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 15 meters in a permanent proportion using an external deaeration vessel. The bubble column reaction vessel includes a cylindrical, vertical section with the inside diameter equal to 6.46 meters, maintaining the surface velocity of the gas phase approximately constant compared to Examples 1 and 2. In order to maintain the same STR as in Example 1, the operation level is slightly changed approximately 26.1 meters from the reaction medium. The height of the lower T to the upper TL of the cylindrical section is 32 meters, the same as in example 1 and which provides the same height of decoupling of free space between the upper part of the reaction medium and the gas outlet of the part above. The top and bottom of the cylindrical section is adjusted with the elliptical heads 2: 1 the height the bottom of the reaction medium to the top of the cylindrical section is approximately 33.6 meters, and the total height of the reaction vessel is of approximately 35.2 meters. The feed is again distributed within the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using a horizontal distributor assembly designed for a substantially uniform feed release over the cross-sectional area lying within a radius of 0.45 * (inner diameter). The air supply is again through a distributor: input oxidant similar to one shown in FIGS. 12-15, and all the oxidant admission holes are located below the lower TL of the cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area in the decoupling zone. The H: W ratio of the reaction medium is markedly reduced to 4.0. The L: D ratio of the reaction vessel is markedly reduced to 5.2. The volume occupied by the reaction medium is approximately 828 cubic meters, and the reaction vessel contains approximately 410,000 grams of suspension. The ratio of the suspension mass to the para-xylene feed ratio is about 8.3 hours. The CTR is approximately 59 kilograms of the para-xylene feed per cubic meter of the reaction medium per hour. The pressure differential of the bottom of the reaction medium to the discharge gas of the top part leaving the reaction vessel is about 0.12 megapascal. The vertical surface area in contact with the reaction medium is approximately 546 square meters which is approximately 324 WminA'H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.52 meters. Under conditions of this example, it is estimated that the acetic acid composition in the reaction medium is desirably returned to the inner level of Example 1, approximately 0.03 kilograms per kilogram of the CTA produced. However, the more diameter of the container used in this example coupled with its smaller H: W ratio leads to very undesirable changes in flow rates, mixing and formation of stages within the reaction medium. This leads to a significant increase in the loss of the para-xylene in the discharge gas from the top and in the formation of undesirable colored by-products. Simply established, the axial flow rates produced by the natural convection forces grow larger in the bubbling columns of the larger diameter even when the surface velocity remains constant. Calculated by a method derived from the Gas-Liquid Recirculation of Gupt model and using a proprietary data base, the maximum upward speed, averaged over time, of the gas phase near the average elevation of the reaction medium is approximately 3.9 meters per second. Similarly calculated, the upward speed averaged over the maximum time of the suspension near the average elevation of the reaction medium is approximately 2.2 meters per second. Similarly calculated, the downward speed averaged over the maximum time of the suspension in the outer ring near the average elevation of the reaction medium is approximately 2. 3 meters per second. Since the height of the reaction medium is little changed between this example and example 1, these increased time-averaged vertical speeds cause the side-by-side mixing times that are reduced significantly in this example as compared to Example 1. This it produces an undesirable increase in the amount of para-xylene migration towards the upper part of the container before oxidation. This leads to an undesirable loss in the performance of the para-xylene that leaves the top of the reaction vessel with the redischarge gas, and changes more of the demand for the dissolved molecular oxygen closer to the top of the reactor where the mole fraction of molecular oxygen is relatively reduced within the gas phase. In addition, the averaged downward velocity in increased time of the suspension in the regions towards the container wall in this example causes more and larger bubbles of the gas phase to be expelled upward against its natural floating in a gravitational field. This leads to an undesirable increase in the recirculation of the partially reduced gas phase of molecular oxygen, which in turn leads to the reduced ability of oxygen dissolved in these regions. Among other effects, this reduced oxygen ability dissolved in several portions of the reaction medium leads to a significantly increased formation ratio of colored, undesirable byproducts in this example compared to Example 1, and this high level of undesirable byproducts renders the product unusable for many applications in PET. Thus, Examples 2 and 3 demonstrate the insufficiency of the prior art to design large-scale oxidation bubbling columns using the primary surface gas velocity (Ug), the L: D ratio, and the average space time ratio of the reaction (STR). EXAMPLE 4 In this example, the members containing pressure of the bubbling column reaction vessel are the same as in Example 3, but the vertical surfaces are added into the reaction medium to impart vertical drag to establish the profiles of reaction cap formation more similar to Example 1, thus restoring product quality and performance of para-xylene, but without increasing the decomposition ratio of acetic acid as in Example 2. The feed ratio of the xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same ratio of 7: 1 to Example 1.

The compositions of the feeds are the same as in Example 1, which provide the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as Example 1. the gas operating pressure of the top part of the reaction vessel is again 0.52 megapascal gauge, and the operating tempera is again approximately 160 ° C measured about the average rise of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 15 meters in a permanent ratio using an external deaeration vessel. The reaction vessel of the bubble column includes a cylindrical section, vertical, with the inside diameter equal to 6.46 meters. The height of the TT. lower than the upper TL of the cylindrical section is 32 meters, and the operation level is approximately 26.3 meters of the reaction medium. The top and bottom of the cylindrical section fit with the elliptical heads of 2.1. The bottom height of the reaction medium to the top of the cylindrical section is approximately 33.6 meters, and the total height of the reaction vessel is approximately 35.2 meters. The feed is distributed again inside the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using an assembly horizontal distributor designed for a substantially uniform release of the feed over the cross-sectional area that lies within a radius of 0. 5 * (inner diameter). The feed of the air again is through an oxidant inlet distributor similar to that shown in FIGS. 12-15, and all the oxidant admission holes are located below the lower TL of the cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the decoupling zone. The bubbling column reaction vessel further includes two orthogonal flat surfaces located with their coincident line intersecting the vertical axis of the symmetry of the cylindrical section. These flat surfaces conveniently comprise metal plate of the same type and surface finish as used in the cylindrical section of the reaction vessel. Each flat surface starts at a lower elevation of 3 meters above the lower TL and extends upwards by 20 meters. The two flat surfaces each substantially substantially substantially extend to the wall of the cylindrical section (i.e., the width of each one is equal to inside diameter) and are supported from the cylindrical section. The thickness and support of the flat surfaces is designed to withstand various forces that may occur in normal and transformed operating conditions. Due to the volume occupied by the plate metal, the operation level is adjusted upwards slightly to 26.3 meters above the bottom of the reaction medium in order to maintain the same STR as in Example 1. Thus, in this example, the medium of reaction is subdivided into four equal sizes and sub-volumes formed for 20 meters outside the total height of the reaction medium. These four sub-volumes communicate with each other both below and above the flat surfaces. Due to the relatively uniform distribution of oxidant and para-xylene feed below the lower end of the flat surfaces, each of the 4 sub-volumes has a similar surface velocity of the gas phase and a similar reaction intensity profile. . The 4 sub-volumes can be accommodated in 4 smaller sized bubble column reaction vessels within the shell of a pressure-containing vessel. The H: W ratio of the reaction medium is 4: 1. The L: D ratio of the reaction vessel is 5.2. The volume occupied by the reaction medium is approximately 828 cubic meters, and the reaction vessel contains approximately 410,000 kilograms of suspension. The ratio of the suspension mass to the feed ratio of the para-xylene is about 8.3 hours. STR is ele about 59 kilograms of para-xylene feed per cubic meter of the reaction medium per hour. The pressure difference of the bottom of the reaction medium to the discharge gas of the top part leaving the reaction vessel is approximately 0.13 megapascal. The vertical surface area in contact with the reaction medium is approximately 1,066 square meters, which is approximately 6.29 * Wmin * H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 0.78 meters. This value is intermediate between Examples 1 and 3, and lies usefully closer to Example 1. Under conditions of this Example it is estimated that the decomposition of acetic acid in the reaction medium is desirably returned to the lower level of Example 1, approximately 0.03. kilograms per kilogram of the CTA produced. The maximum up and down speeds averaged over the gas phase and the suspension phase are reduced in this example as compared to Example 3. This provides useful improvements in the vertical profile of para-xylene, and leads to availability Improved dissolved oxygen in the liquid phase near vertical wall surfaces. Together, these changes improve the performance of para-xylene and reduce the formation of colored byproducts, undesirable in this example as is compared to Example 3. EXAMPLE 5 In this example, the pressure-containing members of the reaction vessel are the same as in Example 3, but the deflector members without fouling are added into the reaction medium to re-establish the step formation profiles. of reaction more similar to Example 1, thus restoring product quality and performance of para-xylene, but without increasing the decomposition ratio of acetic acid as in Example 2. The feed ratio of para-xylene it is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows increase with the same 7: 1 ratio. to Example 1. The compositions of the feeds are the same as in Example 1, which provide the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as Example 1. The operating pressure of the gas from the top of the reaction vessel is again 0.52 megapascal gauge, and the operating temperature is again approximately 160 ° C measured about the average elevation of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 15 meters in a permanent proportion using an external deaeration vessel. The bubble column reaction vessel includes a cylindrical, vertical section with the inside diameter equal to 6.46 meters. The height of the TL lower than the upper TL of the cylindrical section is 32 meters, and the operation level is approximately 26.1 meters of the reaction medium. The top and bottom of the cylindrical section fit with the 2: 1 elliptical heads. The height of the bottom of the reaction medium to the top of the cylindrical section is approximately 33.6 meters, and the total height of the reaction vessel is approximately 35.2 meters. The feed is again distributed within the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using a horizontal distributor assembly designed for a substantially uniform release of the feed over the cross-sectional area lying within a radius of 0.45 A '(inner diameter). The air feed again is through an oxidant inlet distributor similar to one shown in FIGS. 12-15, and all the oxidant admission holes are located below the lower TL of the cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the decoupling zone.

The bubble column reaction vessel further includes a horizontal deviator assembly located in the bubble column at a height of 12 meters above the lower TL of the reaction vessel. This places the diverter assembly approximately 13.6, 2.2 D above the bottom of the reaction medium. This diverter assembly is comprised of 15 individual diverter members. Each diverter member is comprised of an extruded and manufactured L-shape where both extensions of the L-shape are 0.15 meters wide and the included angle between the two extensions is 90 °. The L shapes are all arranged horizontally, parallel to each other, the corners that are directed upwards and are located at the same elevation. The two terminal edges of each L shape are all at the same elevation, below the corners that are directed upwards. When viewed on the end, each member emerges as an inverted B shape. Thus, the percentage of the diverter assembly comprising flat surfaces facing down inclined less than 5 degrees from the horizontal is effectively nothing. The space between the lower edges of each member and its closest neighbor 0.21 meters. The longest of the members has a length effectively equal to the internal diameter of the cylindrical container, which extends diametrically through the wall-to-wall container. The other 14 individual derailleur members are all necessarily shorter in length. All the diverting members are supported on each end by fully extending to the cylindrical stem and joining thereto. Thus, the open area in the elevation of the diverter assembly is approximately 16 square meters, which is approximately 50 percent of the cross-sectional area of the reaction vessel at that elevation. Deflector members are designed to withstand various forces that can occur under normal and disrupted operating conditions. The members are constructed of the same metal as the pipe components used in the assembly of the air sprinkler tube, which metal is properly selected to resist corrosion and erosion. However, the surfaces of the diverting members can be surface finished at 125 RMS or thinner. Despite the precipitation of approximately 76 kilograms per hour of ce into the reaction vessel, the diverter assembly does not get excessively dirty or gives off pieces of solids. The H: W ratio of the reaction medium is 4: 0. The L: D ratio of the reaction vessel is 5.2. The volume occupied by the reaction medium is approximately 828 cubic meters, and the reaction vessel contains approximately 410,000 kilograms of suspension. The ratio of the suspension mass to the feed proportion of the para-xylene is approximately 8.3 hours. The STR is approximately 59 kilograms of para-xylene feed per cubic meter of reaction medium per hour. The pressure difference from the bottom of the reaction medium to the top discharge gas leaving the reaction vessel is approximately 0.13 megapascal. The vertical surface area in contact with the reaction medium is approximately 546 square meters, which is approximately 3.24"i" Wmin? 'H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.52 meters. Under conditions of this example it is estimated that the decomposition of acetic acid in the reaction medium is desirably returned to the lower level of Example 1, approximately 0.03 kilograms per kilogram of produced CTA. The effect of horizontal derailleur mounting is to interrupt vertical velocity and gas phase and suspension within the reaction vessel. This retards the progress of the para-xylene towards the upper surface of the reaction medium, leading to a beneficial reduction in the loss of performance in the para-xylene in the discharge gas from the top. Additionally, the formation of molecular oxide stages and oxidizable compound is improved by providing a reduction in the formation of colored byproducts, undesirable in this example as compared to Example 3. EXAMPLE 6 In this example, the reaction vessel is designed for very high supercharging speeds and gas containment values according to the present invention. The use of a smaller D allows a higher L: D ratio without resorting to an excessively high reaction vessel and without incurring excessive decomposition of the acetic acid solvent. The feed rate of the para-xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same ratio of 7: 1 to Example 1. The feed compositions are the same as in Example 1, which provide the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as Example 1. The operating pressure of the gas at the top of the reaction vessel is again 0.52 megapascal gauge, and the operating temperature is again approximately 160 ° C measured about the average elevation of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 28 meters in a permanent ratio using a container of external deaireration. The bubble column reaction vessel includes a cylindrical, vertical section with the inside diameter equal to 5.00 meters. The height of the TL lower than the upper TL of the cylindrical section is 70 meters. The top and bottom of the cylindrical section fits with the 2: 1 elliptical heads. The bottom height of the reaction medium to the top of the cylindrical section is approximately 71.3 meters, and the total height of the reaction vessel is approximately 72.5 meters. The level of operation is approximately 61.3 meters above the bottom of the reaction medium. The feed is again distributed within the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using a horizontal distributor assembly designed for a substantially uniform release of the feed over the cross-sectional area lying within a 0.45 'radius? (inner diameter). The air feed again is through an oxidant inlet distributor similar to one shown in FIGS. 12-15, and all the oxidant admission holes are located below the lower TL of the cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the decoupling zone. The H: W ratio of the reaction medium is 12.3. The L: D ratio of the reaction vessel is 14.3. The volume occupied by the reaction medium is approximately 1,190 cubic meters, and the reaction vessel contains approximately 420,000 kilograms of suspension. The ratio of the suspension mass to the para-xylene feed ratio is about 8.7 hours. The STR is approximately 419 kilograms of para-xylene feed per cubic meter of the reaction medium per hour. The differential pressure of the bottom of the reaction medium to the discharge gas from the top part leaving the reaction vessel is about 0.21 megapascal. The vertical surface area in contact with the reaction medium is approximately 975 square meters, which is approximately 3.18 * Wmin * H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.22 meters. The relatively small value of D produces a surface velocity of the gas phase at the average height of the reaction medium which is approximately 1.7 times the surface velocity used in Examples 1 to 5. The containment of the gas at the average elevation of medium of reaction is above 0.6. Under the conditions of Example 6 it is estimated that the decomposition of acetic acid in the reaction medium desirably decreases down to 0.03 kilograms per kilogram of CTA produced. This is due to the amount Reduced suspension, more specifically acetic acid, in the reaction vessel compared in Example 3. In this example, the H: W ratio is favorable for reducing end-to-end mixing and for the beneficial formation of molecular oxygen stages. and the oxidizable compound. However, the axial speeds are higher than in Example 1, by accelerating the end mixing for u H: W given. Fortunately, the lower STR reduces the volumetric demand for the transfer of molecular oxygen from the gas to the liquid and the containment of the increased gas serves to increase the capacity to transfer the molecular oxygen from gas to the liquid. In the remainder, the level of production of undesirable colored byproducts is estimated to be comparable to Example 1. EXAMPLE 7 In this example, the reaction vessel is designed for still higher gas surface velocities and gas containment values according to the present invention. An oversized, oversized decoupling zone is used to limit the transportation of the suspension in the overhead discharge gas. The feed rate of the para-xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same ratio 7: to Example 1. The The compositions of the feeds are the same as in Example 1, providing the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in Example 1. The gas operation pressure of the above the reaction vessel is again 0.52 megapascal gauge and the operating temperature is again approximately 160 ° C measured near the average elevation of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 28 meters in a proportion remain using an external deaeration vessel. The reaction vessel of the bubble column includes a cylindrical section, vertical, with the inside diameter at 4.60 meters. The height of the TL lower than the upper end of the cylindrical section is 60 meters. At the upper end of this cylindrical section, a conical section diverges to an inner diameter of 7 meters while it rises in height by 2 meters. The inclination of the conical wall is thus approximately 31 degrees from vertical. The excess of the conical section cs a cylindrical section of gas decoupling with an inner diameter of 7 meters. The height of the upper cylindrical section is 7 meters. The container fits with 2: 1 elliptical heads on the top and bottom. Thus, the combined height of the container of reaction is approximately 71.9 meters. The level of operation is approximately 61.2 meters above the bottom of the reaction medium, placing it close to the union of the middle cylindrical body and the divergence of the conical section. The feed is again distributed within the reaction vessel near an elevation of 2 meters above the bottom of the reaction medium using a horizontal distributor assembly designed for substantially uniform feed release over the cross-sectional area lying within a radio 0.45 (inner diameter). The air feed again is through an oxidant inlet distributor similar to that shown in FIGS 12-15, and all the oxidation inlet holes are located below the lower TL of the lower cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the expanded decoupling section. The H: W ratio of the reaction medium and the L: D ratio of the reaction vessel are 13.3. The X: D ratio of the reaction vessel is 1.5. The L: Y ratio of the reaction vessel is 5.7. The volume occupied by the reaction medium is approximately 320,000 kilograms of suspension. The mass suspension ratio for the para-xylene feed ratio is about 6.5 hours. The STR is approximately 49 kilograms of the Para-xylene feed per cubic meter of the reaction medium per hour. The differential pressure of the bottom of the reaction medium to the discharge gas from the top part leaving the reaction vessel is approximately 0.19 megapascal. The vertical surface area in contact with the reaction medium is approximately 896 square meters, which is approximately 3.19? Wmin? 'H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.12 meters. The relatively small value of D produces a surface velocity of the gas phase at the average height of the reaction medium that is approximately 2 times the surface velocity used in Examples 1 to 5. However, the surface velocity in the coupling section of the coupling Expanded is reduced to about 0.85 times the surface velocity used in Examples 1 to 5. The gas containment at the average elevation of the reaction medium is about 0.7. Under conditions of this Example it is estimated that the decomposition of acetic acid in the reaction medium is desirably reduced below 0.03 kilograms per kilogram of the CTA produced. This is due to the reduced amount of suspension, more specifically acetic acid, in the reaction vessel compared to Example 3. It is estimated that the level of undesirable colored byproducts is lower than in Example 6 due to the formation of stages. improved and the highest gas containment. EXAMPLE 8 In this example, the reaction vessel is the same as in Example 7, but the level of operation rises to be approximately 63.2 meters above the bottom of the reaction medium, placing it near the junction of the divergent conical section and the cylindrical section of expanded gas decoupling. This provides several advantages against the level control in the middle cylindrical body section, which includes a reduced tendency for the upper part of the reaction medium to be very poor foaming and circulation. The feed rate of the para-xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same ratio of 7: 1 to Example 1. The compositions of the feeds are the same. same as in Example 1, providing the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in Example 1. The operating pressure of the gas at the top of the reaction vessel is again 0.52 megapascal gauge and the operating temperature is again approximately 160 ° C measured near the average elevation of the reaction medium. The reaction medium comprising CTA is removed on the side of the reaction vessel at an elevation of 28 meters in a proportion remain using an external deaeration vessel. The ratio II: W of the reaction medium is approximately 13.7, and the ratio L: D of the reaction vessel is 13.3. The volume occupied by the reaction medium is approximately 1.060 cubic meters, and the reaction vessel contains approximately 330,000 kilograms of suspension. The ratio of the mass suspension to the para-xylene feed ratio is approximately 6.8 hours. STR is approximately 46 kilograms of para-xylene feed per cubic meter of reaction medium per hour. The pressure difference of the bottom of the reaction medium to the discharge gas from the top part that leaves the reaction vessel is about 0.20 megapascal. The vertical surface area in contact with the reaction medium is approximately 953 square meters, which is approximately 3.39 * Wmin * H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.11 meters. The surface velocity in the gas phase at the average height of the reaction medium is approximately 2 times the speed used in Examples 1 to 5. The gas containment at the average elevation of the reaction medium is about 0.7. Low In this example, it is estimated that the decomposition of acetic acid in the reaction medium desirably decreases below 0.03 kilograms per kilogram of the CTA produced. This is due to the reduced amount of suspension, more specifically acetic acid, in the reaction vessel compared to Example 3. It is estimated that the level of the undesirable colored by-products is lower than in Example 6 due to the improved stage formation and the containment of gas. EXAMPLE 9 In this example, the members containing pressure of the reaction vessel are the same as in Example 7, but the internal members used to introduce the oxidant and the para-xylene are modified significantly to provide multiple vertically separate entries for each . The feed rate of the para-xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same 7: 1 ratio to Example 1. The feed compositions are the same as in Example 1, providing the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in Example 1. The operating pressure of the gas in the upper part of the reaction is again 0.52 megapascal gauge and the operating temperature is again approximately 160 ° C measured near the average elevation of the reaction medium. The reaction medium comprising CTA is removed from the side of the reaction vessel at an elevation of 28 meters in a permanent ratio using an external deaeration vessel. The bubble column vessel includes the same oxidizing distributor in the bottom head in the reaction vessel as in Example 8. However, only 70 pnt of the total gas phase oxidant stream is introduced via the lower distributor. The other 30 pnt of the oxidant in the gas phase is introduced via a high oxidant inlet distributor. This flow relationship is imposed by the flow control coils which use control valves and flow transmitters conveniently located on the supply ducts for compressed air external to the reaction vessel. The elevated oxidant distributor comprises a horizontal, mitred, box-shaped flow conduit, rather than an octagonal, as used in the lower elliptical head. The box-shaped conduit conveniently comprises nominal 14-inch Schedule IOS pipe materials. The distance of the centroid on one side of the centroid on the opposite side is a meter. The high oxidant distributor comprises approximately 60 gas phase oxidation release holes, all 0.03 meters in diameter and near the bottom of the conduit approximately 14 meters above the bottom of the reaction medium. This high oxidant distributor serves at least two useful functions. First, the oxidant flow injected downward into the reaction medium interrupts the axial velocity profile that rises along the vertical axis of symmetry of the cylindrical section. This imposes a useful hydraulic diverter to decrease the extension of para-xylene in the upper regions of the reaction medium, relating to the loss of performance of the top part and to reduce the demand for dissolved oxygen in the upper regions. Few meters above the high oxidation inlet, the natural convention flow pattern is reorganized by itself to run up along the central axis of symmetry, but the hydraulic diverter is nonetheless effective. Second, the majority of the heat of reaction is removed from the reaction medium via the evaporation of the solvent, and most of this evaporation occurs near the oxidant feed sites. By vertically separating the location of the introduction of the parts of the oxidation current in gas phase, the vertical profile of the temperature in the reaction medium is adjust The bubble column reaction vessel includes two para-xylene inlet distributors similar to one in Example 8. The lower para-xylene inlet manifold is located to provide a substantially uniform 50 percent release of the liquid phase over the area of the cross section lying within a radius of 0.45 * (inner diameter) at a lower elevation of 2 meters above the bottom of the reaction. The upper para-xylene inlet distributor is located to provide a substantially uniform 50 percent release of the liquid phase feed over the cross-sectional area that lies within a radius of 0.45 * (inner diameter) in elevation higher than 10 meters above the bottom of the reaction medium. This flow ratio is imposed by the flow control coils using control valves and flow transmitters suitably located on the supply conduits for the liquid phase feed external to the reaction vessel. In this example, the operation level rises to be approximately 63.7 meters above the bottom of the reaction medium, placing it just above the divergent conical section and in the expanded gas decoupling cylindrical section. The H: W ratio of the medium of reaction is approximately 13.8, and the ratio L: D of the reaction vessel is 13.3. The volume occupied by the reaction medium is approximately 1070 cubic meters, and the reaction vessel contains approximately 340,000 kilograms of suspension. The ratio of the mass suspension to the para-xylene feed ratio is approximately 6.9 hours. STR is approximately 46 kilograms of para-xylene feed per cubic meter of reaction medium per hour. The differential pressure of the bottom of the reaction medium to the top discharge gas leaving the reaction vessel is about 0.20 megapascal. The vertical surface area in contact with the reaction medium is approximately 975 square meters, which is approximately 3.47 * 3Wmin * H. The volume ratio of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.10 meters. The surface velocity of the gas phase at the average height of the reaction medium is about 2 times the surface velocity used in Examples 1 to 5. EXAMPLE 10 In this example, the reaction vessel is designed with three different cylindrical diameters different elevations, with the average elevation diameter that is smaller. This configuration benefits the section lower cylindrical, where the liquid feed stream and the gas phase oxidant first enters, with a relatively larger mass of liquid phase for the initial dilution and para-xylene reaction where oxygen is still more abundant; the middle cylindrical section, where the molecular oxygen decreases incrementally, with a relatively larger gas containment and proportion of mass transfer from gas to liquid; and the cylindrical upper part, which is a gas decoupling zone, with a relatively low gas phase velocity to limit the transportation of the suspension in the discharge gas of the upper part. The feed rate of the para-xylene is again 49,000 kilograms per hour - 7 times larger than in Example 1. The other feed flows are increased with the same ratio of 7: 1 to Example 1. The feed compositions are the same as in Example 1, providing the same concentrations of water, cobalt, bromine and manganese within the liquid phase of the reaction medium as in Example 1. The operating pressure of the gas at the top of the reaction vessel is again 0.52 megapascal gauge, and the operating temperature is again roughly * 160 ° C measured near the average elevation of the reaction. The reaction medium comprising CTA is removed from the reaction vessel at an elevation of 28 meters in a permanent ratio using an external deaeration vessel. The bubble column includes three cylindrical, vertical sections of different diameters. The lower cylindrical section has an inner diameter of 6.46 meters, giving a surface velocity of the gas phase in this section approximately equal to the surface velocity of Example 1. The height of this lower cylindrical section of the lower TL to the upper end is 8 meters At the upper end of this lower cylindrical section, a conical section converges to an inner diameter of 4.5 meters while it rises in height by one meter. The inclination of this conical wall is thus approximately 44 degrees from the vertical, the excess of the lower conical section, the middle cylindrical section has an inner diameter of 4.5 meters, giving a superficial velocity of the gas phase in this section above 2 times the superficial velocity in the lowest cylindrical section. The height of the middle cylindrical section is 45 meters. At the upper end of the middle cylindrical section, a conical section diverges to a diameter of 7 meters while it rises in height by 2 meters. The inclination of the conical wall is thus approximately 32 degrees from the vertical, the excess of the upper conical divergence section is a section cylindrical gas decoupling with an internal diameter of 7 meters. The height of the upper cylindrical section is 7 meters. The container fits with 2: 1 elliptical heads on the top and bottom. Thus, the combined height of the reaction vessel is approximately 66.4 meters. The level of operation is approximately 57.6 meters above the bottom of the reaction medium, placing it near the junction of the divergent conical section and the upper cylindrical section. The feed is again distributed within the reaction vessel near an elevation of 2 meters above the bottom using a horizontal distributor assembly designed for a substantially uniform feed release over the cross-sectional area lying within a radius of 0.45 * (diameter inside) . The air feed again is through an oxidant inlet manifold similar to that shown in FIGS 12-15, and all the oxidation admission holes are located below the lower TL of the lower cylindrical section. The reflux solvent is distributed as droplets over essentially the entire cross-sectional area of the upper cylindrical section. The volume occupied by the reaction medium is approximately 1,080 cubic meters, and the reaction vessel contains approximately 400,000 kilograms of suspension. The mass ratio of suspension to the proportion Para-xylene feed is about 8.1 hours. STR is approximately 45 kilograms of para-xylene feed per cubic meter of reaction medium per hour. T.a differential pressure from the bottom of the reaction medium to the dirge gas from the top leaving the reaction vessel is about 0.20 megapascal. The vertical surface area in contact with the reaction medium is approximately 944 square meters, which is approximately 3.64 * Wmin? "H and approximately 2.34 * Wmax * H. The ratio of the volume of the reaction medium to the vertical surface area in contact with the reaction medium is approximately 1.14 meters The ratio of L]: Dx is approximately 1.5: 1. The ratio of Lu: Du is approximately 10: 1. The ratio of L?: Lu is approximately 0.2. : 1. The ratio of de X: Di is approximately 1.1: 1. The ratio of LU: Y is approximately 4.2: 1. The ratio of Lt: D is approximately 0.15: 1. The largest diameter in the The base of the reactor provides a large suspension mass near the introduction zone for para-xylene feed, where liquid flows and mixing are very important to provide feed dilution to avoid colored, coupled aromatic impurities. , this di larger meter places a larger fraction medium of reaction under more head pressure of the suspension above, promoting the partial pressure of oxygen and the transfer of mass of molecular oxygen from the gas to the liquid. The elongated medium cylindrical section, of smaller diameter provides the formation of reagent stages and the containment of the high gas; this improves the equalization of the reaction demand for the dissolved oxygen with the mass transfer supply of the rising gas phase, where the oxygen is consumed incrementally and its partial pressure declines. The invention has been described in detail with particular reference to preferred embodiments thereof, but it will be understood that variations and modifications can be made within the spirit and scope of the invention.

Claims (1)

1. CLAIMS 1. A process, characterized in that it comprises: oxidizing an oxidizable compound in a liquid phase of a multi-phase reaction medium contained in a reaction zone of an initial oxidation reactor, wherein the oxidation is carried out in a manner such that when the full volume of the reaction medium is theoretically divided into 2,000 discrete horizontal cuts of equal volume, less than 120 of the horizontal cuts have a gas containment less than 0.3 on a time-averaged and volume-averaged basis. 2. The process according to claim 1, characterized in that the entire volume of the reaction medium has a gas containment of at least about 0.4 on a time averaged and averaged basis in volume. 3. The process according to claim 1, characterized in that less than 80 of the horizontal cuts have a gas containment less than 0.3 on a time averaged and averaged basis in volume. 4. The process according to claim 1, characterized in that less than 40 of the horizontal cuts have a gas containment less than 0.3 on a time-averaged basis and averaged over volume, wherein the entire volume of the reaction medium has a gas containment in the range of about 0.6 to about 0.9 on an averaged and averaged basis in volume. 5. The process according to claim 1, characterized in that the initial oxidation reactor is a stirred reactor. 6. The process according to claim 1, characterized in that the initial oxidation reactor in a bubble column reactor. The process according to claim 6, characterized in that the process further comprises deaerating a portion of the reaction medium in a deaeration zone separated from the reaction zone, to thereby provide a substantially deaerated suspension comprising less than about 5 percent by volume of gas, wherein the deaeration is caused mainly by the natural flotation of the gas phase of the reaction medium in the solid and liquid phases of the reaction medium. 8. The process according to claim 7, characterized in that the deaeration zone is defined between one or more vertical side walls of a deaeration vessel, wherein the maximum horizontal cross-sectional area of the area of deaeration is less than about 25 percent of the maximum horizontal cross-sectional area of the reaction zone. 9. The process according to claim 8, characterized in that at least a portion of the deaeration zone is located in the reactor. 10. The process according to claim 8, characterized in that the entire deaeration zone is located outside the reactor. The process according to claim 6, characterized in that the reaction medium has a maximum height (H), a maximum width (W), and an H: W ratio greater than about 3: 1. 12. The process according to claim 11, characterized in that the H: W ratio is in the range of about 8: 1 to about 20: 1. The process according to claim 11, characterized in that the process further comprises introducing a predominantly gas phase oxidant stream comprising molecular oxygen in the reaction zone, where most of the molecular oxygen enters the reaction zone within approximately 0.25W of the bottom of the reaction zone. 14. The process in accordance with the claim 13, characterized in that the majority of molecular oxygen enters the reaction zone within about 0.2W and about 0.02H from the bottom of the reaction zone. 15. The process according to claim 13, characterized in that the molecular oxygen enters the reaction zone in such a way that when the reaction zone is theoretically divided into 4 vertical quadrants of equal volume by a pair of vertical planes of intersection, no more than about 80 weight percent of the molecular oxygen enters the reaction zone in only one of the vertical quadrants. The process according to claim 13, characterized in that at least a portion of the reaction zone is defined by one or more vertical side walls of the reactor, wherein at least about 25 weight percent of the molecular oxygen enters the reactor. in the reaction zone in one or more inwardly spaced locations at least 0.05D of the vertical side walls, wherein the reaction zone has a maximum diameter (D). The process according to claim 13, characterized in that a first portion of the oxidant stream is introduced into the reaction zone via one or more oxidant orifices. bottoms, wherein a second portion of the oxidant stream is introduced into the reaction zone via one or more of the lower oxidant orifices, wherein the orifices of. Higher oxidants are located at least 1W above the lower oxidant orifices. 18. The process according to claim 17, characterized in that the first and second portions of the oxidant stream each contain less than about 50 mole percent molecular oxygen. 19. The process according to claim 17, characterized in that at least 10 mol percent of the total amount of molecular oxygen introduced into the reaction zone is introduced via the lower oxidation orifices, whereby less about 10 mole percent of the total amount of molecular oxygen introduced into the reaction zone is introduced via the top oxidizer orifices. The process according to claim 17, characterized in that the upper oxidant orifices are located at least about 2D above the lower oxidant orifices, wherein the first and second portions of the oxidant stream each contain less than 40 percent molecular mole of oxygen. 2 i. The process in accordance with the - > 1 J claim 1, characterized in that the oxidizable compound is an aromatic compound. 22. The process according to claim 1, characterized in that the oxidizable compound is para-xylene. 23. The process according to claim 1, characterized in that the oxidation causes at least about 10 weight percent of the oxidizable compound to form solids in the reaction medium. 24. The process according to claim 1, characterized in that the oxidation is carried out in the presence of a catalyst system comprising cobalt. 25. The process according to claim 24, characterized in that the catalyst system further comprises bromine and manganese. 26. The process according to claim 1, characterized in that the oxidation in the initial oxidation reactor causes the formation of terephthalic acid in the reaction medium, wherein the process further comprises subjecting at least a portion of the terephthalic acid to the oxidation in a secondary oxidation reactor. 27. The process according to claim 26, characterized because the oxidation in the The secondary oxidation reactor is carried out at an average temperature of at least about 10 ° C higher than the oxidation in the initial oxidation reactor. The process according to claim 26, characterized in that the oxidation in the secondary oxidation reactor is carried out at an average temperature in the range of about 20 to about 80 ° C higher than the average temperature of the initial oxidation reactor. , wherein the oxidation in the initial oxidation reactor is carried out at an average temperature of about 140 to about 180 ° C, wherein the oxidation in the secondary oxidation reactor is carried out at an average temperature in the range of about 180 to about 220 ° C. 29. The process according to claim 1, characterized in that the oxidation causes the formation of crude terephthalic acid particles in the reaction medium, wherein a representative sample of the crude terephthalic acid particles has one or more of the following characteristics: (i) contains less than about 12 ppmw of 4,4-dicarboxystilbene (4, 4 -DCS), (ii) contains less than about 800 ppmw of isophthalic acid (IPA), (iii) contains less than about 100 ppmw of 2, 6-dicarboxyfluorenone (2,6-DCF), (iv) has a percent transmittance at 340 nanometers (% T340) greater than about 25. 30. A process, characterized in that it comprises: (a) introducing a current of feed comprising para-xylene in a reaction zone of a bubble column reactor; (b) introducing an oxidant stream comprising molecular oxygen in the reaction zone, wherein the reaction zone has a maximum diameter (D), wherein the majority of the molecular oxygen enters the reaction zone within about 0.25D from the bottom of the reaction zone; and (c) oxidizing at least a portion of the para-xylene in a liquid phase of a three phase reaction medium contained in the reaction zone, wherein the oxidation causes at least about 10 weight percent of the -xylene forms raw terephthalic particles in the reaction medium. 31. The process according to claim 30, characterized in that the reaction medium has a maximum height (H), wherein most of the oxygen Molecule enters the reaction zone within about 0.025H from the bottom of the reaction zone. 32. The process according to claim 31, characterized in that most of the molecular oxygen enters the reaction zone within about 0.2D and about 0.02H from the bottom of the reaction zone. 33. The process according to claim 31, characterized in that the majority of the molecular oxygen enters the reaction zone within about 0.15D and 0.015H from the bottom of the reaction zone. 34. The process according to claim 30, characterized in that the process further comprises deaerating a portion of the reaction medium in a deaeration zone separated from the reaction zone to thereby provide a substantially deaerated suspension comprising less than about 5 percent by volume of gas, wherein the deaeration is mainly caused by the natural flotation of the gas phase of the three phase reaction medium in the solid and liquid phases of the three phase reaction medium. 3b. The process according to claim 34, characterized in that the deaeration zone is defined between one or more side walls verticals of a deaeration vessel, wherein the maximum horizontal cross-sectional area of the deaeration zone is less than about 25 percent of the maximum horizontal cross-sectional area of the reaction zone. 36. The process according to claim 30, characterized in that the reaction medium comprises in the range of about 5 to about 40 weight percent solids on a time averaged and averaged basis in volume. 37. The process according to claim 30, characterized in that the oxidation is carried out in such a way that when the entire volume of the reaction medium is theoretically divided into 2,000 discrete horizontal cuts of equal volume, less than 120 of the cuts horizontals have a gas containment of less than 0.3 on a time-averaged and averaged-in-volume basis. 38. The process according to claim 30, characterized in that the process further comprises subjecting at least a portion of the crude terephthalic acid particles to oxidation in a secondary oxidation reactor. 39. The process according to claim 30, characterized in that a sample Representative of the crude terephthalic acid particles has one or more of the following characteristics: (i) it contains less than about 12 ppmw of 4,4-dicarboxystilbene (4, 4 -DCS), (i) it contains less than about 800 ppmw of isophthalic acid (IPA), (iii) contains less than about 100 ppmw of 2,6-dicarboxyfluorenone (2,6-DCF), (iv) has a percent transmittance at 340 nanometers (% T340) greater than about 25. 40. In a bubble column reactor for reacting a predominantly liquid phase stream and a predominantly gas phase stream, the improvement characterized in that it comprises: a container shell defining a reaction zone which is elongated along the length of a central axis, wherein the reaction zone has a normally lower end and a normally superior end spaced from one to the other by a maximum axial distance (L), wherein the reaction zone has a diametr or maximum (D), wherein the reaction zone has an L: D ratio of at least about 6: 1; and one or more gas orifices to discharge the current in gas phase in the reaction zone, wherein most of the cumulative open area defined by all gas orifices is located within about 0.25D of the normally lower end of the reaction zone. 41. The bubble column reactor according to claim 40, characterized in that the majority of the cumulative open area defined by all the gas orifices is located within about 0.022L of the normally lower end of the reaction zone. 42. The bubble column reactor according to claim 40, characterized in that substantially all of the cumulative open area defined by all gas orifices is located within about 0.25D and about 0.022L of the normally lower end of the reaction zone. 43. The bubble column reactor according to claim 40, characterized in that at least two of the gas orifices are spaced axially from one another by at least about ID. 44. The bubble column reactor according to claim 40, characterized in that the reactor further comprises one or more liquid orifices for discharging the liquid phase stream in the reaction zone, wherein at least 30 percent of the cumulative open area defined by all liquid orifices is located within approximately 1.5D of the oxidant orifice located closest to the normally lower end. 45. The bubble column reactor according to claim 44, characterized in that the reactor comprises at least two liquid orifices spaced from each other by at least about 0.5D. 46. The bubble column reactor according to claim 40, characterized in that L is in the range of about 20 to about 75 meters, D is in the range of about 2 to about 10 meters, and the ratio L: D is in the range of about 8: 1 to about 20: 1. 47. The bubble column reactor according to claim 40, characterized in that the reactor further comprises a deaeration vessel defining an inlet and an outlet, wherein the inlet is in fluid communication with the reaction zone, wherein the outlet is normally placed below the inlet, where the deaeration vessel comprises a wall normally vertical side that extends at least partially between the inlet and the outlet and that defines a deaeration zone, wherein the deaeration zone has a maximum horizontal cross-sectional area that is less than about 25 percent of the sectional area Maximum horizontal cross section of the reaction zone. 48. The bubble column reactor according to claim 47, characterized in that the deaeration zone is at least partially placed in the container shell. 49. The bubble column reactor according to claim 47, characterized in that the deaeration zone is located completely outside the container shell. 50. The bubble column reactor according to claim 40, characterized in that the gas orifices are configured in such a way that when the reaction zone is theoretically divided into 4 vertical quadrants of equal volume by a pair of vertical planes of intersection, no more than about 80 percent of the cumulative open area defined by all gas orifices is located in a common vertical quadrant. 51. The bubble column reactor according to claim 40, characterized in that at least a portion of the reaction zone is defined by one or more vertical side walls of the reactor, wherein at least 25 percent of the cumulative open area defined by all gas orifices is attributable to the gas orifices spaced apart in at least 0.05D of the vertical side walls.