CN214598924U - Micro-interface preparation device of butanol and octanol - Google Patents

Abstract

The utility model provides a little interface preparation facilities of butyl octanol, include: the system comprises a oxo-synthesis tower, an isomer separator, a first hydrogenation reactor and a hydrogen cylinder; the oxo-column is connected to the isomerate separator; the first hydrogenation reactor comprises a reactor body, a circulating pipeline is arranged on one side of the reactor body, an inlet of the circulating pipeline is communicated with the upper part of the reactor body, and an outlet of the circulating pipeline is communicated with the lower part of the reactor body; two opposite distributors are arranged in the reactor body; a hemispherical catalyst ejector is arranged on the side wall of the reactor body; the catalyst injector is disposed between the two distributors in a vertical direction. The utility model discloses a little interface preparation facilities material conversion rate is high, the energy consumption is low, with low costs, the security is high, required reaction temperature and pressure are low, side reaction is few, is worth extensively popularizing and applying.

Description

Micro-interface preparation device of butanol and octanol

Technical Field

The utility model relates to an acrylic hydroxylation preparation field particularly, relates to a micro-interface preparation facilities of butyl octanol.

Background

The butanol and octanol are important raw materials for synthesizing fine chemical products, the yield of the butanol and octanol in China is huge at present and accounts for about 21% of the total amount of the world, the butanol and octanol take synthesis gas and propylene as raw materials, and the n-isobutyraldehyde is generated through formylation reaction to obtain n-isobutanol, and the octanol can also be obtained through the condensation and the addition of unsaturated bonds of two molecules of n-butanol, so the octanol is habitually called as the butanol and octanol. The butanol and octanol have the typical characteristics of alcohol organic matters, have special smell, are colorless transparent and flammable liquids, have moderate toxicity and can form an azeotrope with water. The method is mainly used for producing plasticizers, solvents, dehydrating agents, defoaming agents, dispersing agents, flotation agents, petroleum additives, synthetic spices and the like. Due to its wide use, the yield and the amount of butanol and octanol are also increased year by year.

The major production methods of butanol and octanol include fermentation, acetaldehyde condensation, and propylene oxo synthesis, which is a major method for producing butanol and octanol, and is rapidly developing with significant advantage worldwide.

The method for preparing butanol and octanol by the propylene oxo synthesis method comprises the following steps:

(1) butyraldehyde generation: taking synthesis gas and propylene as raw materials, taking rhodium carbonyl, triphenylphosphine complex or other similar substances used in industry as catalysts, reacting to produce mixed butyraldehyde, separating the catalysts, and then further rectifying and separating to obtain a butyraldehyde mixture;

(2) production of butanol: the butyraldehyde mixture enters a butyraldehyde hydrogenation system to generate butanol, and the butanol is rectified to remove light and heavy components and separate isomers to obtain n-butanol and isobutanol;

(3) and (3) generating octanol: n-butyl aldehyde enters a condensation system for carbonyl condensation to produce octenal, and then the light and heavy components are removed by hydrogenation and rectification to finally produce octanol.

The main equation for the preparation of butanol and octanol by the propylene oxo process is as follows:

(1) hydroformylation of propylene to form n-butyraldehyde (n-Bal):

CH₃CH＝CH₂+CO+H₂→CH₃CH₂CH₂CHO

(2) hydroformylation of propylene to isobutyraldehyde (i-Bal):

CH₃CH＝CH₂+CO+H₂→CH₃CH₂(CHO)CH₃

(3) mixed butyraldehyde is hydrogenated to generate isobutanol and n-butanol:

CH₃CH₂CH₂CHO+H₂→CH₃CH₂CH₂CH₂OH

CH₃CH₂(CHO)CH₃+H₂→CH₃CH(CH₃)CH₂OH

(4) condensation of n-butyraldehyde to produce 2-ethyl-3-propylacrolein (EPA):

2CH₃CH₂CH₃CHO→CH₃CH₂CH₂CH＝C(C₂H5)CHO+H₂O

(5) hydrogenation of 2-ethyl-3-propylacrolein to octanol:

CH₃CH₂CH₂CH＝C(C₂H₅)CHO+2H₂→CH₃CH₂CH₂CH(CH₂CH₃)CH₂OH

chinese patent publication No.: CN103012089A discloses a method for synthesizing propylene by carbonyl, which comprises feeding propylene, stripping synthesis gas and hydroformylation catalyst solution into a first butyraldehyde condensation unit for contact reaction, feeding foam components containing hydroformylation catalyst in the butyraldehyde condensation unit into a first separator for separation, feeding a part of the obtained gas phase components back, feeding the other part of the obtained gas phase components, synthesis gas and hydroformylation catalyst solution into a second butyraldehyde condensation unit for contact reaction, and feeding foam components containing hydroformylation catalyst in the butyraldehyde condensation unit into a second separator for separation; feeding at least part of the liquid phase at the bottom of the first and second oxo butyraldehyde condensation unit and the synthesis gas into a stripping tower for stripping, obtaining liquid phase components at the bottom of the tower, and obtaining the stripped synthesis gas at the top of the tower; and (3) feeding the liquid-phase component at the bottom of the stripping tower into a separation tower for separation, collecting a butyraldehyde crude product at the tower top, and collecting a catalyst solution at the tower bottom. The method can effectively improve the utilization rate of the propylene and reduce the content of the propylene in the tail gas. It can be seen that the method has the following problems:

firstly, in the method, propylene and synthesis gas are contacted with a catalyst only through a first oxo butyraldehyde condensation unit, and a gas-phase component enters the first oxo to form large bubbles, but the gas-phase component cannot be fully contacted with a liquid-phase component catalyst due to overlarge bubble volume, so that the reaction efficiency of the system is reduced.

Secondly, the reaction rate of the synthesis gas and the propylene with the catalyst is reduced in the method, so that the utilization rate of the propylene and the synthesis gas is reduced, the waste of raw materials is caused to a great extent, the production cost of the butanol and the octanol is increased, and the requirement of the existing circular economy is not met.

Thirdly, the method does not consider the problems of small phase interface area, serious liquid drop coagulation phenomenon, low reaction efficiency and the like in the mixed butyraldehyde hydrogenation reaction.

Fourthly, in the method, a fixed bed reactor is used for hydrogenation reaction, and because the fixed bed reactor is a strong exothermic reaction, a large amount of heat needs to be removed in the process, and the reaction energy consumption is large and the efficiency is low.

In view of this, the present invention is especially provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a micro-interface preparation device of butanol and octanol, the reaction system respectively crushes mixed butyraldehyde and hydrogen into micron-sized bubbles before hydrogenation reaction by arranging a micro-interface generator so as to improve the mass transfer area and the reaction efficiency of phase boundary; the micro-bubble generator is arranged to disperse and crush the octenal and the hydrogen into micro-sized micro-bubbles, so that the mass transfer area of a phase boundary between the octenal and the hydrogen is increased, and the conversion rate of the octenal is increased; by providing distributors at the outlets of the micro-interface generator and the micro-bubble generator, uniform distribution of micro-bubbles can be promoted.

In order to realize the above purpose of the utility model, the following technical scheme is adopted:

the utility model provides a little interface preparation facilities of butyl octanol, include: the system comprises a oxo-synthesis tower, an isomer separator, a first hydrogenation reactor and a hydrogen cylinder; the oxo-column is connected to the isomerate separator; the first hydrogenation reactor comprises a reactor body, a circulating pipeline is arranged on one side of the reactor body, an inlet of the circulating pipeline is communicated with the upper part of the reactor body, and an outlet of the circulating pipeline is communicated with the lower part of the reactor body; two opposite distributors are arranged in the reactor body; a hemispherical catalyst ejector is arranged on the side wall of the reactor body; the catalyst injector is arranged between the two distributors along the vertical direction;

the isomerate separator is provided with a n-butyl aldehyde outlet and a mixed butyraldehyde outlet; the mixed butyraldehyde outlet is connected with a first micro-interface generator, and the first micro-interface generator is connected with the distributor positioned above the reactor body;

the hydrogen cylinder is connected with the distributor which is positioned below in the reactor body, and a first bubble generator and a second micro-interface generator are sequentially arranged between the hydrogen cylinder and the distributor which is positioned below; hydrogen is dispersed and crushed into micro bubbles in a micron level by the first bubble generator and the second micro interface generator and then enters the reactor body through the distributor;

the n-butyl aldehyde outlet is connected with an n-butyl aldehyde tower; a product outlet of the n-butyraldehyde tower is sequentially connected with a condensation reactor, a gas-liquid separator and a second hydrogenation reactor, and the structure of the second hydrogenation reactor is the same as that of the first hydrogenation reactor; an evaporator is arranged between the gas-liquid separator and the second hydrogenation reactor, and an outlet of the evaporator is connected with a second micro-bubble generator; the second microbubble generator is connected with the distributor positioned below in the second hydrogenation reactor;

the distributor positioned above in the second hydrogenation reactor is connected with the hydrogen cylinders; and a second bubble generator and a first micro-bubble generator are sequentially arranged between the hydrogen cylinder and the distributor positioned above the hydrogen cylinder in the second hydrogenation reactor along the air inlet direction.

In the prior art, mixed butyraldehyde is generally subjected to direct hydrogenation to prepare mixed butanol and octenal is generally subjected to direct hydrogenation reaction, but the hydrogenation reaction does not consider that the phase boundary mass transfer area of the mixed butyraldehyde and hydrogen is small, the reaction is insufficient, and the conversion rate is low; similarly, the transformation ratio of the octenal is low and the reaction efficiency is low because the mass transfer area of the boundary of the octenal and the hydrogen phase is small.

In order to solve the technical problem, the utility model provides a micro-interface preparation facilities of butyl octanol, this preparation facilities will mix butyraldehyde and hydrogen breakage formation diameter to be greater than or equal to 1 μm, and the micron order bubble of < 1mm is in order to improve phase boundary mass transfer area respectively through setting up first micro-interface generator and second micro-interface generator before hydrogenation, reduce liquid film thickness, reduce mass transfer resistance, and mix solvent and micron order bubble after the breakage and form the gas-liquid emulsion, with mass transfer efficiency and the reaction efficiency of intensive mixing butyraldehyde and hydrogen within the scope of predetermined operating condition; the first micro-bubble generator and the second micro-bubble generator are arranged to disperse and crush octenal and hydrogen into micro-sized micro-bubbles respectively, so that the mass transfer area of a phase boundary between the octenal and the hydrogen is increased, and the conversion rate of the octenal is increased; by arranging the distributors inside the first hydrogenation reactor and the second hydrogenation reactor, uniform distribution of micro-bubbles can be promoted.

Preferably, the distributor is conical, and the section of the distributor increases along the flowing direction of the bubbles; a plurality of air holes are distributed on the circumferential surface of the distributor; micro-bubbles are ejected along the air holes to achieve uniform distribution of micro-bubbles.

Preferably, a plurality of bubble generating layers are arranged in the first bubble generator and the second bubble generator; the bubble generation layer is formed by piling round granular particles with the same diameter.

Preferably, the first bubble generator is connected with an n-butanol pipeline for providing a liquid phase environment for the dispersion and fragmentation of the hydrogen gas.

Preferably, a catalyst inlet, a propylene inlet and a synthesis gas inlet are sequentially arranged on the side wall of the oxo-synthesis tower, and a sprayer, a hydraulic micron bubble generator and a pneumatic micron bubble generator are sequentially arranged in the oxo-synthesis tower from top to bottom; the sprayer is connected with the catalyst inlet, the hydraulic micron bubble generator is connected with the propylene inlet, and the pneumatic micron bubble generator is connected with the synthesis gas inlet.

Preferably, the outlets of the hydraulic micron bubble generator and the pneumatic micron bubble generator are opposite.

Preferably, guide discs are arranged at outlets of the hydraulic micron bubble generator and the pneumatic micron bubble generator; the guide disc is conical, and a plurality of guide holes are uniformly distributed in the guide disc.

The utility model discloses a set up hydraulic drive formula micron bubble generator and pneumatic micron bubble generator and carry out the dispersion breakage to hydrogen and synthetic gas respectively in the oxo process tower, make hydrogen and synthetic gas before the oxo process reaction, change gaseous pressure energy or the kinetic energy of liquid into bubble surface energy and transmit for propylene and synthetic gas, make propylene and synthetic gas breakage form the diameter and be greater than or equal to 1 mu m, and the micron order bubble of < 1mm is with the mass transfer area between improvement catalyst and propylene and synthetic gas, reduce liquid film thickness, reduce the mass transfer resistance, and mix solvent and micron order bubble after the breakage and form the gas-liquid emulsion, with mass transfer efficiency and reaction efficiency between propylene and synthetic gas and catalyst in the operating condition within range of predetermineeing. The guide disc is arranged at the outlet, so that micro bubbles are distributed more uniformly; the outlets of the hydraulic micron bubble generator and the pneumatic micron bubble generator are opposite, so that two paths of micro bubbles generate a hedging effect, and the distribution of the micro bubbles is further promoted.

It should be noted that the utility model discloses when arranging, the formula micron bubble generator that surges and propylene access connection, pneumatic type micron bubble generator and synthetic gas access connection, and the formula micron bubble generator that surges sets up the top at pneumatic type micron bubble generator. The synthesis gas is synthesized in advance relatively to the gas source, and the raw materials belong to flammable and explosive gases, so in order to improve the safety of the synthesis gas, the position of an air inlet of the synthesis gas is set to be lower as much as possible, and meanwhile, in view of the fact that the synthesis gas flows towards the top more easily after entering the interior of the oxo-synthesis tower, a hydraulic micron bubble generator for crushing propylene is arranged at the upper part, and a pneumatic micron bubble generator for crushing the synthesis gas is arranged at the lower part.

The utility model discloses a set up first micro-interface generator and second micro-interface generator and will mix butyraldehyde and hydrogen breakage respectively before hydrogenation and form the diameter and be greater than or equal to 1 mu m, and less than 1 mm's micron order bubble in order to improve the phase boundary mass transfer area, reduce liquid film thickness, reduce mass transfer resistance, and mix solvent and micron order bubble after the breakage and form the gas-liquid emulsion, in order to strengthen mass transfer efficiency and the reaction efficiency who mixes between butyraldehyde and hydrogen within the scope of predetermined operating condition; the first micro-bubble generator and the second micro-bubble generator are arranged to disperse and crush octenal and hydrogen into micro-sized micro-bubbles respectively, so that the mass transfer area of a phase boundary between the octenal and the hydrogen is increased, and the conversion rate of the octenal is increased; the two distributors are arranged, the outlets of the two distributors are opposite, micro bubbles can be promoted to be uniformly distributed, and the catalyst is sprayed by the catalyst sprayer, so that the contact area of the catalyst and the raw material is increased, and the reaction rate is improved; the first bubble generator and the second bubble generator are arranged, so that gas can be dispersed into large bubbles in advance, and the subsequent micro-interface dispersing efficiency is improved.

Additionally, the utility model discloses a still be provided with circulation pipeline on the hydrogenation ware, circulation pipeline drives the solvent and carries out the circulation flow, and the bubble is smugglied secretly among the circulation process, can promote the contact reaction of two kinds of raw materials microbubble, improves reaction efficiency. It is thus clear that the utility model discloses an improve hydrogenation ware to use bubble generater, gas distributor and little interface generator jointly, improved the application effect at little interface.

It will be appreciated by those skilled in the art that the micro-interface generator of the present invention has been embodied in the prior patents of the present invention, such as the patents having application numbers CN201610641119.6, CN201610641251.7, CN201710766435.0, CN106187660, CN105903425A, CN109437390A, CN205833127U and CN 207581700U. The detailed structure and operation principle of the micro bubble generator (i.e. micro interface generator) is described in detail in the prior patent CN201610641119.6, which describes that "the micro bubble generator comprises a body and a secondary crushing member, wherein the body is provided with a cavity, the body is provided with an inlet communicated with the cavity, the opposite first end and second end of the cavity are both open, and the cross-sectional area of the cavity decreases from the middle of the cavity to the first end and second end of the cavity; the secondary crushing member is disposed at least one of the first end and the second end of the cavity, a portion of the secondary crushing member is disposed within the cavity, and an annular passage is formed between the secondary crushing member and the through holes open at both ends of the cavity. The micron bubble generator also comprises an air inlet pipe and a liquid inlet pipe. "the specific working principle of the structure disclosed in the application document is as follows: liquid enters the micro-bubble generator tangentially through the liquid inlet pipe, and gas is rotated at a super high speed and cut to break gas bubbles into micro-bubbles at a micron level, so that the mass transfer area between a liquid phase and a gas phase is increased, and the micro-bubble generator in the patent belongs to a pneumatic micro-interface generator.

In addition, the first patent 201610641251.7 describes that the primary bubble breaker has a circulation liquid inlet, a circulation gas inlet and a gas-liquid mixture outlet, and the secondary bubble breaker communicates the feed inlet with the gas-liquid mixture outlet, which indicates that the bubble breakers all need to be mixed with gas and liquid, and in addition, as can be seen from the following drawings, the primary bubble breaker mainly uses the circulation liquid as power, so that the primary bubble breaker belongs to a hydraulic micro-interface generator, and the secondary bubble breaker simultaneously introduces the gas-liquid mixture into an elliptical rotating ball for rotation, thereby realizing bubble breaking in the rotating process, so that the secondary bubble breaker actually belongs to a gas-liquid linkage micro-interface generator. In fact, no matter be the hydraulic formula micro-interface generator, still gas-liquid linkage micro-interface generator all belongs to a specific form of micro-interface generator, however the utility model discloses the micro-interface generator who adopts is not limited to above-mentioned several kinds of forms, and the specific structure of the bubble breaker who records in the patent in advance is only one of them form that the micro-interface generator can adopt.

Furthermore, the prior patent 201710766435.0 states that the principle of the bubble breaker is that high-speed jet flows are used to achieve mutual collision of gases, and also states that the bubble breaker can be used in a micro-interface strengthening reactor to verify the correlation between the bubble breaker and the micro-interface generator; moreover, in the prior patent CN106187660, there is a related description on the specific structure of the bubble breaker, see paragraphs [0031] to [0041] in the specification, and the accompanying drawings, which illustrate the specific working principle of the bubble breaker S-2 in detail, the top of the bubble breaker is a liquid phase inlet, and the side of the bubble breaker is a gas phase inlet, and the liquid phase coming from the top provides the entrainment power, so as to achieve the effect of breaking into ultra-fine bubbles, and in the accompanying drawings, the bubble breaker is also seen to be of a tapered structure, and the diameter of the upper part is larger than that of the lower part, and also for better providing the entrainment power for the liquid phase.

Because the initial stage of earlier patent application, little interfacial surface generator just has just developed, so the early name is micron bubble generator (CN201610641119.6), bubble breaker (201710766435.0) etc. along with continuous technological improvement, later stage renames as little interfacial surface generator, now the utility model provides a little interfacial surface generator is equivalent to micron bubble generator, bubble breaker etc. before, and only the name is different. To sum up, the utility model discloses a little interface generator belongs to prior art.

Preferably, the second bubble generator is connected with an octanol pipeline to provide a liquid phase environment for the dispersion and fragmentation of hydrogen.

Preferably, the first hydrogenation reactor is sequentially connected with a first rectifying tower and an alcohol product separation device, and the mixed butanol generated by the first hydrogenation reactor is rectified and purified by the first rectifying tower and then is separated into n-butanol and isobutanol by the alcohol product separation device.

Preferably, a product outlet of the second hydrogenation reactor is connected with a second rectifying tower, and octanol generated by the second hydrogenation reactor is purified by the second rectifying tower and then discharged.

Preferably, the bottom of the oxo column is provided with a solvent inlet. The solvent is n-butyraldehyde.

Preferably, a demister is disposed between the oxo tower and the isomer separator, and a product of the oxo tower is defoamed by the demister and then flows into the isomer separator.

Preferably, a catalyst circulation device for supplementing a catalyst is connected to each of the oxo tower, the first hydrogenation reactor and the second hydrogenation reactor.

Compared with the prior art, the beneficial effects of the utility model reside in that:

(1) the utility model discloses a preparation facilities will mix butyraldehyde and hydrogen breakage respectively before hydrogenation through setting up the micro-interface generator and form the diameter to be greater than or equal to 1 mu m, and less than 1 mm's micron order bubble in order to improve the phase boundary mass transfer area, reduce liquid film thickness, reduce the mass transfer resistance to mix solvent and micron order bubble after the breakage and form the gas-liquid emulsion, in order to strengthen mass transfer efficiency and the reaction efficiency who mixes between butyraldehyde and hydrogen within the scope of predetermined operating condition;

(2) the micro-bubble generator is arranged to disperse and crush the octenal and the hydrogen into micro-sized micro-bubbles, so that the mass transfer area of a phase boundary between the octenal and the hydrogen is increased, and the conversion rate of the octenal is increased;

(3) by providing distributors at the outlets of the micro-interface generator and the micro-bubble generator, uniform distribution of micro-bubbles can be promoted.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

fig. 1 is a schematic structural diagram of a butanol-octanol micro-interface preparation device provided in embodiment 1 of the present invention;

fig. 2 is a schematic structural diagram of a first hydrogenation reactor provided in embodiment 1 of the present invention;

fig. 3 is a schematic structural diagram of a distributor provided in embodiment 1 of the present invention;

fig. 4 is a schematic bottom view of a distributor provided in embodiment 1 of the present invention;

fig. 5 is a schematic structural diagram of a first bubble generator provided in embodiment 1 of the present invention.

Description of the drawings:

a 10-oxo column; 101-catalyst inlet;

102-a propylene inlet; 103-a syngas inlet;

104-solvent inlet; 105-a sprayer;

106-hydraulic micron bubble generator; 107-guide disc;

108-pneumatic micro bubble generator; 20-a demister;

30-an isomer separator; 301-mixed butyraldehyde outlet;

a 302-n-butyraldehyde outlet; 40-a first hydrogenation reactor;

401-a first micro-interface generator; 402-a second micro-interface generator;

403-a distributor; 4031-stomata;

404-a circulation line; 405-a circulation pump;

406-a catalyst injector; 50-a first rectification column;

a 60-alcohol product separation unit; 70-hydrogen gas cylinder;

80-a first bubble generator; 801-bubble generation layer;

an 802-n-butanol line; a 90-n-butyraldehyde column;

100-a condensation reactor; 110-an alkali liquor storage tank;

120-a gas-liquid separator; 130-a second bubble generator;

1301-octanol tubing; 140-an evaporator;

150-a second hydrogenation reactor; 1501-a first microbubble generator;

1502-a second microbubble generator;

160-a second rectification column; 170-catalyst circulation device.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings and detailed description, but those skilled in the art will understand that the following described embodiments are some, not all, of the embodiments of the present invention, and are only used for illustrating the present invention, and should not be construed as limiting the scope of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention. The examples, in which specific conditions are not specified, were conducted under conventional conditions or conditions recommended by the manufacturer. The reagents or instruments used are not indicated by the manufacturer, and are all conventional products available commercially.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In order to clarify the technical solution of the present invention, the following description is made in the form of specific embodiments.

Example 1

As shown in fig. 1 to 5, this embodiment provides a micro-interface preparation device for butanol and octanol, comprising: a oxo column 10, an isomerate separator 30 and a first hydrogenation reactor 40; the oxo column 10 is connected to an isomerate separator 30; a demister 20 is provided between the oxo tower 10 and the isomer separator 30, and the product of the oxo tower 10 is defoamed by the demister 20 and then flows into the isomer separator 30.

Wherein, the bottom of the oxo-tower 10 is provided with a solvent inlet 104. The side wall of the oxo-synthesis tower 10 is sequentially provided with a catalyst inlet 101, a propylene inlet 102 and a synthesis gas inlet 103, and the oxo-synthesis tower 10 is internally provided with a sprayer 105, a hydraulic micron bubble generator 106 and a pneumatic micron bubble generator 108 from top to bottom; the sprayer 105 is connected with the catalyst inlet 101, the hydraulic micron bubble generator 106 is connected with the propylene inlet 102, and the pneumatic micron bubble generator 108 is connected with the synthesis gas inlet 103. The outlets of the hydrodynamic microbubble generator 106 and the pneumatic microbubble generator 108 are opposite.

The outlets of the hydrodynamic microbubble generator 106 and the hydrodynamic microbubble generator 108 are both provided with guide discs 107; the guide disk 107 is conical and has a plurality of guide holes uniformly distributed thereon.

As shown in fig. 2, the first hydrogenation reactor 40 includes a reactor body, a circulation pipeline 404 is disposed on one side of the reactor body, and a circulation pump 405 is disposed on the circulation pipeline 404; an inlet of the circulating pipeline 404 is communicated with the upper part of the reactor body, and an outlet of the circulating pipeline 404 is communicated with the lower part of the reactor body; two opposite distributors 403 are arranged in the reactor body; the distributor 403 positioned above is higher than the position where the circulating pipeline 404 is connected with the reactor body in the vertical direction, and the distributor 403 positioned below is lower than the position where the circulating pipeline 404 is connected with the reactor body in the vertical direction; a hemispherical catalyst injector 406 is arranged on the side wall of the reactor body; the catalyst injector 406 is disposed between the two distributors 403 in the vertical direction. During reaction, the catalyst is injected between the two raw material bubbles through the catalyst injector 406, and the catalytic reaction is efficiently performed.

As shown in fig. 3-4, the sparger 403 is tapered, with the cross-section of the sparger 403 increasing in the direction of bubble flow; a plurality of air holes 4031 are distributed on the circumferential surface of the distributor 403; the microbubbles are ejected along the gas holes 4031 to achieve uniform distribution of the microbubbles.

The isomer separator 30 is provided with a n-butyl aldehyde outlet 302 and a mixed butyraldehyde outlet 301; the mixed butyraldehyde outlet 301 is connected with a first micro-interface generator 401, and the first micro-interface generator 401 is connected with a distributor 403 positioned above the reactor body;

wherein, the hydrogen cylinder 70 is connected with the distributor 403 which is positioned at the lower part in the reactor body, and a first bubble generator 80 and a second micro-interface generator 402 are sequentially arranged between the hydrogen cylinder 70 and the distributor 403 which is positioned at the lower part; after being dispersed and crushed into micro-bubbles at the micron level by the first bubble generator 80 and the second micro-interface generator 402, the hydrogen enters the reactor body through the distributor 403; the first bubble generator 80 is connected with an n-butanol pipeline 802 for providing a liquid phase environment for the dispersion and fragmentation of hydrogen.

The n-butyraldehyde outlet 302 is connected with the n-butyraldehyde tower 90; the product outlet of the n-butyraldehyde tower 90 is connected with a condensation reactor 100, a gas-liquid separator 120 and a second hydrogenation reactor 150 in sequence. The top of the condensation reactor 100 is connected with an alkali liquor storage tank 110. In this embodiment, the second hydrogenation reactor 150 is identical in structure to the first hydrogenation reactor 40; an evaporator 140 is arranged between the gas-liquid separator 120 and the second hydrogenation reactor 150, and the outlet of the evaporator 140 is connected with a second microbubble generator 1502; the second microbubble generator 1502 is connected to the distributor 403 positioned below in the second hydrogenation reactor 150;

specifically, the distributor 403 positioned above in the second hydrogenation reactor 150 is connected to the hydrogen cylinders 70; the second bubble generator 130 and the first microbubble generator 1501 are sequentially arranged between the hydrogen cylinder 70 and the distributor 403 positioned above in the second hydrogenation reactor 150 along the air inlet direction. The second bubble generator 130 is connected with an octanol pipeline 1301 for providing a liquid phase environment for the dispersion and fragmentation of hydrogen.

Since the first micro-interface generator 401, the second micro-interface generator 402, the first micro-bubble generator 1501 and the second micro-bubble generator 1502 need to participate in the liquid phase for the dispersion and the fragmentation of the gas, the first micro-interface generator 401 and the second micro-interface generator 402 are both connected with the first hydrogenation reactor 40 to introduce the solvent in the first hydrogenation reactor 40, and the first micro-bubble generator 1501 and the second micro-bubble generator 1502 are both connected with the second hydrogenation reactor 150 to introduce the solvent in the second hydrogenation reactor 150.

As shown in fig. 5, a plurality of bubble generation layers 801 are disposed inside the first bubble generator 80 and the second bubble generator 130; the bubble generation layer 801 is formed by stacking round granular particles having the same diameter.

In this embodiment, the first hydrogenation reactor 40 and the second hydrogenation reactor 150 are slurry bed reactors.

In this embodiment, the solvent in the oxo tower 10 is n-butyraldehyde, the solvent in the first hydrogenation reactor 40 is n-butanol, and the solvent in the second hydrogenation reactor 150 is octanol.

In order to promote the recycling of the catalyst, a catalyst recycling device 170 for replenishing the catalyst is connected to each of the oxo tower 10, the first hydrogenation reactor 40 and the second hydrogenation reactor 150.

During the specific operation, propylene gas and synthesis gas are introduced into the oxo-synthesis tower 10, the reaction temperature in the oxo-synthesis tower 10 is set to 80 ℃, the reaction pressure is set to 0.8MPa, the hydraulic micron bubble generator 106 and the pneumatic micron bubble generator 108 respectively break the propylene and the synthesis gas into micron-scale micro-bubbles, and the micro-bubbles are released into the oxo-synthesis tower 10, so that the materials are fully contacted, and the oxo-synthesis reaction is carried out.

The oxo reaction product is conveyed to the isomer separator 30, and the mixed butyraldehyde is crushed into micro-bubbles with a micron scale by the first bubble generator 80 and the first micro-interface generator 401, and is released into the first hydrogenation reactor 40, so that the mixed butyraldehyde is fully contacted with hydrogen to perform hydrogenation reaction. The reaction temperature in the first hydrogenation reactor 40 is set to 60 ℃ and the reaction pressure is set to 0.50 MPa. The produced mixed butanol is rectified and purified in the first rectifying tower 50, and then n-butanol and isobutanol are separated in the alcohol product separating device 60.

The n-butyraldehyde enters an n-butyraldehyde tower 90 for purification, heavy components are removed, the purified n-butyraldehyde enters a condensation reactor 100 for condensation reaction, the reaction temperature is set to 65 ℃, and the reaction pressure is set to 0.23 MPa.

The condensation reaction product is gasified by the evaporator 140, then dispersed and crushed into microbubbles under the action of the microbubble generator, enters the second hydrogenation reactor 150, and is subjected to hydrogenation reaction with hydrogen, and the hydrogenation reaction product is rectified by the second rectifying tower 160 to obtain octanol. The reaction temperature in the second hydrogenation reactor 150 is set to 60 ℃ and the reaction pressure is set to 0.50 MPa.

And rectifying and purifying the obtained hydrogenation reaction product, and separating into n-butanol and isobutanol by a separation tower. Through detection, after the system and the process are used, the conversion rate of propylene is 98.5%, the conversion rate of butyraldehyde is 96.5%, and the synthesis efficiency of the process is improved by 3.8%.

Example 2

The production apparatus of this example was identical to that of example 1 except that the reaction temperature in the oxo column 10 in this example was set to 88 ℃ and the reaction pressure was set to 1.1 MPa; the reaction temperature in the condensation reactor 100 was set to 70 ℃ and the reaction pressure was set to 0.25 MPa; the reaction temperature in the first hydrogenation reactor 40 is set to 70 ℃, and the reaction pressure is set to 0.70 MPa; the reaction temperature in the second hydrogenation reactor 150 is set to 70 ℃ and the reaction pressure is set to 0.70 MPa.

Through detection, after the device and the process are used, the conversion rate of propylene is 99.0%, the conversion rate of butyraldehyde is 98.0%, and the synthesis efficiency of the process is improved by 4.2%.

Example 3

The production apparatus of this example was identical to that of example 1 except that the reaction temperature in the oxo column 10 in this example was set to 95 ℃ and the reaction pressure was set to 1.3 MPa; the reaction temperature in the condensation reactor 100 was set at 75 ℃ and the reaction pressure was set at 0.28 MPa; the reaction temperature in the second hydrogenation reactor 150 is set to 78 ℃, and the reaction pressure is set to 0.80 MPa; the reaction temperature in the first hydrogenation reactor 40 was set at 78 deg.c and the reaction pressure was set at 0.80 MPa.

Through detection, after the device and the process are used, the conversion rate of propylene is 99.3%, the conversion rate of butyraldehyde is 98.5%, and the synthesis efficiency of the process is improved by 4.8%.

In a word, compare with the reaction system of prior art's propylene carbonylation system butyl octanol, the utility model discloses a butyl octanol's micro-interface preparation facilities material conversion rate is high, the energy consumption is low, with low costs, the security is high, required reaction temperature and pressure are low, side reaction is few, is worth extensively popularizing and applying.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (8)

1. A micro-interface preparation device of butanol and octanol is characterized by comprising: the system comprises a oxo-synthesis tower, an isomer separator, a first hydrogenation reactor and a hydrogen cylinder; the oxo-column is connected to the isomerate separator; the first hydrogenation reactor comprises a reactor body, a circulating pipeline is arranged on one side of the reactor body, an inlet of the circulating pipeline is communicated with the upper part of the reactor body, and an outlet of the circulating pipeline is communicated with the lower part of the reactor body; two opposite distributors are arranged in the reactor body; the distributor above is higher than the position where the circulating pipeline is connected with the reactor body along the vertical direction, and the distributor below is lower than the position where the circulating pipeline is connected with the reactor body along the vertical direction; a hemispherical catalyst ejector is arranged on the side wall of the reactor body; the catalyst injector is arranged between the two distributors along the vertical direction;

the isomerate separator is provided with a n-butyl aldehyde outlet and a mixed butyraldehyde outlet; the mixed butyraldehyde outlet is connected with a first micro-interface generator, and the first micro-interface generator is connected with the distributor positioned above the reactor body;

the hydrogen cylinder is connected with the distributor which is positioned below in the reactor body, and a first bubble generator and a second micro-interface generator are sequentially arranged between the hydrogen cylinder and the distributor which is positioned below; hydrogen is dispersed and crushed into micro bubbles in a micron level by the first bubble generator and the second micro interface generator and then enters the reactor body through the distributor;

the n-butyl aldehyde outlet is connected with an n-butyl aldehyde tower; a product outlet of the n-butyraldehyde tower is sequentially connected with a condensation reactor, a gas-liquid separator and a second hydrogenation reactor, and the structure of the second hydrogenation reactor is the same as that of the first hydrogenation reactor; an evaporator is arranged between the gas-liquid separator and the second hydrogenation reactor, and an outlet of the evaporator is connected with a second micro-bubble generator; the second microbubble generator is connected with the distributor positioned below in the second hydrogenation reactor;

the distributor positioned above in the second hydrogenation reactor is connected with the hydrogen cylinders; and a second bubble generator and a first micro-bubble generator are sequentially arranged between the hydrogen cylinder and the distributor positioned above the hydrogen cylinder in the second hydrogenation reactor along the air inlet direction.

2. The apparatus for producing a butanol-octanol micro interface according to claim 1, wherein said distributor is tapered, and a cross section of said distributor increases in a direction of flow of bubbles; a plurality of air holes are distributed on the circumferential surface of the distributor; micro-bubbles are ejected along the air holes to achieve uniform distribution of micro-bubbles.

3. The device for preparing a micro interface between butanol and octanol according to claim 1, wherein each of the first bubble generator and the second bubble generator has a plurality of bubble generation layers disposed therein; the bubble generation layer is formed by piling round granular particles with the same diameter.

4. The apparatus for preparing a micro-interface between butanol and octanol according to claim 1, wherein the first bubble generator is connected with an n-butanol line for providing a liquid phase environment for the dispersive disruption of hydrogen.

5. The micro-interface preparation device of butanol and octanol according to claim 1, wherein the side wall of the oxo-synthesis tower is provided with a catalyst inlet, a propylene inlet and a synthesis gas inlet in sequence, and the oxo-synthesis tower is internally provided with a sprayer, a hydraulic micron bubble generator and a pneumatic micron bubble generator from top to bottom in sequence; the sprayer is connected with the catalyst inlet, the hydraulic micron bubble generator is connected with the propylene inlet, and the pneumatic micron bubble generator is connected with the synthesis gas inlet.

6. The apparatus of claim 5, wherein the outlets of the hydrodynamic microbubble generator and the pneumatic microbubble generator are opposite.

7. The apparatus of claim 6, wherein the outlet of the hydrodynamic microbubble generator and the outlet of the pneumatic microbubble generator are provided with guide discs.

8. The apparatus of claim 7, wherein the pilot disc is tapered and has a plurality of pilot holes uniformly distributed therein.

Images