CN114904408B - Ethylene and oxygen mixer - Google Patents

Abstract

The invention discloses an ethylene and oxygen mixer, which comprises a cylinder body, a layered partition plate, a distribution plate, a spray ring, an ethylene inlet and an oxygen inlet; one end of the spray ring is fixed on the distribution plate; the space between the distribution plate and the closed end of the cylinder forms a feeding area, the space in the cylinder where the distribution plate and the injection ring are positioned forms a distribution area, and the space between the injection ring and the open end of the cylinder forms a jet flow mixing area; the layering partition plate divides the feeding zone into an ethylene feeding zone and an oxygen feeding zone, and is respectively connected with an ethylene inlet and an oxygen inlet; the distribution plate and the injection ring divide the distribution area into ethylene annular channels and oxygen annular channels which are alternately arranged from outside to inside along the radial direction of the cylinder; ethylene channel holes are formed in the distribution plate in the ethylene feeding area and correspond to the corresponding ethylene annular channels; and oxygen channel holes are formed in the distribution plate in the oxygen feeding area and correspond to the corresponding oxygen annular channels. The invention can lead the ethylene and the oxygen to be far away from an explosion zone after being uniformly mixed, thereby achieving the aim of safety.

Description

Ethylene and oxygen mixer

Technical Field

The invention belongs to the technical field of mixers, and particularly relates to an ethylene and oxygen mixer.

Background

Ethylene Oxide (EO) is an important chemical product of downstream derivatives of ethylene industry, is second to polyethylene, has wide application field, is mainly used for producing fine chemical products such as nonionic surfactants, ethanol adhesives, ethylene glycol vinegar, polymerase polyols, choline oxide, medicines and the like, and can also be used as a disinfectant for medical equipment such as foods, cosmetics, surgical equipment and the like. The downstream products of the ethylene oxide can reach 6000 or more, and the production has wide prospect.

The industrial production technology of ethylene oxide mainly comprises a chlorohydrin method and an ethylene direct oxidation method, wherein the chlorohydrin method is mainly used in the early stage, and because chlorine gas is used in the production process of the chlorohydrin method and a large amount of hydrogen chloride is generated, the corrosion damage to equipment, buildings and auxiliary facilities is serious, and in addition, waste water, waste gas and waste materials are difficult to treat, the chlorohydrin method is basically replaced by the ethylene direct oxidation method. The direct ethylene oxidation method can be divided into an air oxidation method and an oxygen oxidation method according to different oxidants, and the air oxidation method is usually low in operation cost, good in catalyst selectivity, high in investment and low in conversion rate, and the current mainstream production method is the oxygen oxidation method for synthesizing ethylene oxide through the reaction of ethylene and oxygen. At this time, the mixing of ethylene and oxygen is necessary to be completed before the reaction, but ethylene is inflammable and explosive, and has a wide explosion range, and if the explosion accident is extremely easy to occur due to improper control, the danger is extremely high, so that the mixing of ethylene and oxygen is a key process and equipment for producing ethylene oxide.

The mixing method commonly used in the current industrial production mainly comprises stirring mixing, static mixer mixing and jet flow mixing. The stirring and mixing mainly uses external mechanical energy such as mechanical stirring to strengthen macroscopic mixing of fluid, but because chemical products are easy to be inflammable and explosive, extremely toxic and easy to react when heated, the mechanical stirring is likely to provide spark and heat required by combustion, and moving parts are difficult to seal and easy to leak, the stirring and mixing is difficult to be used for mixing ethylene and oxygen. The static mixer is generally provided with structures such as a baffle plate in a mixer or a pipeline to disturb fluid flow, increase the speed gradient of laminar flow movement of the fluid or form turbulence to realize mixing of the fluid, but the mixing explosion range of ethylene and oxygen is wider, the mixing proportion of the static mixer is difficult to control, and precise mixing of the ethylene and the oxygen is difficult to realize, so that the static mixer is also difficult to be used for mixing the ethylene and the oxygen.

Jet mixing is the use of the high velocity jet entrainment effect by injecting a fast moving fluid (i.e., jet) into a slow flowing or stationary fluid (i.e., main fluid) to form a mixed layer at the jet boundary due to the velocity differential between the jet and main fluid. The mixing layer expands along the flow direction of the jet, and the main fluid enters the jet through entrainment and mixing, so that the two fluids are uniformly mixed. The mixing mode in industrial production is realized due to the advantages of simple structure, no rotating parts, reliable operation, intense mixing, high mass and heat transfer rate and the like.

The ethylene-oxygen mixer applied in industry at present is usually used as a mixing mode of main flow side feeding and jet flow as tubular feeding, and the jet flow is in single-point injection in general, so that the circumferential direction is uneven and the jet flow mixing effect is poor; the flow direction of the main flow is changed after the main flow enters the mixer laterally, the flow in the mixer is uneven, the impact on the tube array is large, the tube array is easy to break, the structural design is unreasonable, and continuous improvement is needed.

Patent CN 105214528A discloses a mixer of olefin and oxygen, which is mainly characterized in that a plurality of oxygen dispersing pipes are symmetrically arranged at the tail end of an oxygen pipeline, a plurality of oxygen dispersing holes are uniformly distributed on each oxygen dispersing pipe, and the oxygen pipeline is communicated with a mixing chamber through the oxygen dispersing holes. However, in the cross section of the olefin pipe, the oxygen-dispersed holes are denser at the center of the pipe and sparser near the wall surface. In the mixing process, the concentration of oxygen at the center of the main pipe is possibly higher than that near the wall surface, the mixing is uneven, the mixing effect is affected, and safety accidents are easily caused.

Patent CN 108310989B discloses a rapid mixing device for ethylene and oxygen, a plurality of oxygen spiral distributing pipes are arranged in a mixing chamber, the plane of each spiral distributing pipe is vertical to the flowing direction of ethylene, a plurality of oxygen nozzles are uniformly distributed on each spiral distributing pipe, the direction of each nozzle is consistent with the flowing direction of ethylene, ethylene entering from a main flow channel is rapidly mixed with oxygen sprayed from each spiral distributing pipe nozzle in the mixing region, and the mixing of ethylene and oxygen is better solved. However, as the oxygen feeding pipeline is divided into a plurality of distribution pipes at the main pipeline to enter the ethylene main pipeline, oxygen in each oxygen branch pipe may be different, so that the oxygen is unevenly mixed in the mixing area, the mixing effect is affected, and safety accidents are easily caused.

In summary, the mixing of ethylene and oxygen is an important production link, and the mixing process should traverse the explosion region, so that the risk is extremely high, and the ethylene and oxygen must be uniformly mixed and kept away from the explosion region during the mixing process. The current jet flow mixing technology has the technical problems of uneven mixing and easy safety accidents, and needs to be further improved.

Disclosure of Invention

In order to solve the technical problems of uneven mixing and easy safety accidents in the prior art, the invention provides the ethylene and oxygen mixer, so that ethylene and oxygen rapidly pass through an explosion interval in the mixing process, and are uniformly mixed and then are far away from the explosion interval, thereby achieving the aim of safety.

The invention provides an ethylene and oxygen mixer which comprises a cylinder body, a layered partition plate, a distribution plate, a spray ring, an ethylene inlet and an oxygen inlet; the cylinder body is cylindrical, one end of the cylinder body is closed, and the other end of the cylinder body is open; the spray ring is cylindrical with two open ends; the distribution plate is fixed in the cylinder, and one end of the injection ring is fixed on the distribution plate along the axis of the cylinder and is coaxially arranged with the cylinder; the space between the distribution plate and the closed end of the cylinder forms a feeding area, the space in the cylinder where the distribution plate and the injection ring are positioned forms a distribution area, and the space between the injection ring and the open end of the cylinder forms a jet flow mixing area; the layering partition plate is positioned in the feeding area, is vertically fixed on the distribution plate along the axis of the cylinder body, divides the feeding area into an ethylene feeding area and an oxygen feeding area, and is connected with the ethylene feeding area and the oxygen feeding area; the distribution plate and the injection ring divide the distribution area into annular channels with the diameters from large to small along the radial direction of the cylinder body, the annular channels are divided into ethylene annular channels and oxygen annular channels, and the ethylene annular channels and the oxygen annular channels are alternately arranged along the radial direction of the cylinder body from outside to inside; ethylene channel holes are formed in the distribution plate in the ethylene feeding area and correspond to the corresponding ethylene annular channels; and oxygen channel holes are formed in the distribution plate in the oxygen feeding area and correspond to the corresponding oxygen annular channels.

The specific number of the spray rings can be determined according to the actual working conditions, and is preferably 2-12, preferably 3-8. The large spray ring and the small spray ring are nested layer by layer along the radial direction of the cylinder body and are coaxially arranged with the cylinder body.

The cylinder body can be composed of a shell and a sealing head, and the sealing end can be sealed in the form of the sealing head or a flange cover; the open end is used for allowing the mixed gas after mixing to enter a subsequent flow; the cylinder is preferably a cylinder with a diameter of 200-3000 mm for the purpose of easy manufacture and uniform distribution.

The number of the layered separators can be determined according to actual working conditions, and is preferably 2-6, and more preferably 3-5. The layering partition plates and the distribution plates divide the feeding area of the cylinder into two types of ethylene feeding areas and oxygen feeding areas, the two types of feeding areas are alternately distributed along the circumferential direction of the cylinder, and each ethylene feeding area and each oxygen feeding area are closed areas; each closed area should be tightly sealed, and material channeling is forbidden; and a corresponding ethylene inlet or an oxygen inlet is arranged on the corresponding cylinder body of each closed area for external oxygen or ethylene to enter. The number of the layering partition plates is increased, the number of the ethylene feeding area and the oxygen feeding area can be increased, the rapid and uniform diffusion of ethylene and oxygen in the distribution area in the respective annular channels is promoted, the maximum distance of circumferential diffusion is reduced, the uniformity of ethylene and oxygen in the respective annular channels is increased, and the rectifying length and the jet ring length are shortened.

Because only ethylene channel holes corresponding to the ethylene annular channels are formed in the distribution plate of the ethylene feeding area, only oxygen channel holes corresponding to the oxygen annular channels are formed in the distribution plate of the oxygen feeding area, ethylene and oxygen enter the respective annular channels through the respective channel holes without being mixed with each other, and subsequent jet mixing is performed.

The sealing of the two sides of the spray ring and the distribution plate should be performed by reliable means such as welding, bonding, etc., and the sealing of the mixer must be performed due to the wide explosion range of ethylene and oxygen and extremely high risk. In general, the seal of the injection ring with the distribution plate should ensure that oxygen is only transported within the oxygen annular channel to the jet mixing zone, does not enter the ethylene annular channel, and must not diffuse into the ethylene region at the forward end of the ethylene annular channel; ethylene does not enter the oxygen annular channel, is only conveyed to the jet mixing zone in the ethylene annular channel, and cannot diffuse to the oxygen area at the front end of the oxygen annular channel, so that the intrinsic safety of the mixer is ensured.

In order to ensure that the ethylene and the oxygen form jet flow mixing, the ethylene annular channels and the oxygen annular channels are alternately arranged, and the radial width of the ethylene annular channels is larger than that of the oxygen annular channels.

As a modification, the annular channel of the outermost ring of the distribution area is an ethylene annular channel.

The determination of the spray ring length may take into account the following two aspects:

on the one hand, after oxygen enters the oxygen annular channel from the oxygen channel holes on the distribution plate, the oxygen diffuses to the area in the oxygen annular channel, in which no oxygen directly enters, and then enters the jet flow mixing area after the oxygen is uniformly distributed in the oxygen annular channel. The oxygen annular channel plays roles in guiding oxygen and rectifying oxygen, and the oxygen is uniformly distributed in the annular direction in the oxygen annular channel, so that the injection ring is required to have a certain axial length;

on the other hand, after the ethylene enters the ethylene annular channel from the ethylene channel holes on the distribution plate, the ethylene is diffused in the ethylene annular channel to a region where the ethylene does not directly enter, and when the ethylene is uniformly distributed in the ethylene annular channel, the ethylene enters the jet mixing region. The injection ring is used for rectifying the ethylene in the circumferential direction, so that the ethylene is uniformly distributed in the ethylene annular channel in the circumferential direction, and therefore, the injection ring is required to have a certain axial length;

the final length of the spray ring takes the largest of the lengths determined by both and leaves a certain margin to provide greater operational flexibility.

As a further improvement, in order to shorten the rectifying length of the ethylene by the jet ring in the distribution area, promote the ethylene to diffuse to the ethylene annular channel area without direct feeding of ethylene, reduce the lengths of the jet ring and the mixer, continuously or discontinuously set up ethylene baffles on the inner wall of the ethylene annular channel corresponding to the ethylene channel holes, the height of the ethylene baffles is smaller than the radial width of the ethylene annular channel, preferably smaller than 1/2 of the radial width of the ethylene annular channel, so as to increase the flow resistance of the ethylene after entering the ethylene annular channel, promote the ethylene to flow to the ethylene annular channel position without direct opening of the ethylene channel holes, and ensure that the ethylene is uniformly distributed in the annular channel in a shorter distance.

After ethylene and oxygen are rectified by the jet ring and distributed uniformly in the respective annular channels, the ethylene and the oxygen enter the jet mixing area. The total area of the cross section of the oxygen annular channel is smaller than the total area of the oxygen inlet, the conveying speed of oxygen in the oxygen annular channel is increased to 20-100 m/s, the fast moving oxygen fluid is injected into the relatively low-speed main fluid, namely ethylene flow, at the jet boundary, a mixed layer is formed due to the speed difference of the oxygen jet and the ethylene main fluid, and the mixed layer is expanded along the flow direction of the oxygen jet, and the main fluid ethylene enters the oxygen jet through entrainment and mixing, so that the purposes of fast passing through the explosion range and fast mixing are achieved. When the size of the annular channel, the position of the injection ring and the position of the ethylene channel hole are designed, oxygen injected from different oxygen annular channels must not cross and strike the wall surface within a certain distance, so as to realize the control of the mixing proportion of oxygen and ethylene, and avoid explosion. After the ethylene and oxygen are mixed in the jet mixing zone, they are far from the explosive range and leave the mixer.

As a further improvement, the ethylene and oxygen mixer can be provided with an electrostatic grounding device so as to eliminate the influence of static electricity on the mixing process, prevent static electricity accumulation, increase the safety of the mixer and increase the intrinsic safety.

As a further improvement, considering the extremely high risk of the mixer, an explosion-proof wall can be arranged outside the ethylene and oxygen mixer, so that the loss of extreme accident conditions is minimized.

As a further improvement, in view of the extremely high risk of the mixer, the ethylene and oxygen mixer may be provided with an interlock control system to reduce the oxygen supply or to introduce an inert gas such as nitrogen from the oxygen inlet to keep the mixing process away from the explosion limit when the oxygen content at the point of measurement is out of specification.

The invention has the following beneficial effects:

1) By utilizing the spraying and entrainment of high-speed oxygen, ethylene and oxygen are quickly mixed through explosion limit and quick mixing, so that the physical domain and time domain of the mixing process are reduced, and the aim of safe mixing is fulfilled;

2) The diversion effect of the coaxially arranged multi-layer injection rings realizes that ethylene and oxygen enter the mixer in the same direction, and oxygen is uniformly and continuously sprayed out from oxygen annular channels with different diameters to the inner ring of the mixer, so that the mixing is easy to be uniform, and the operation elasticity is high; the accurate mixing of ethylene and oxygen is realized by setting the flow velocity of the oxygen jet flow and the position of the jet flow;

3) The safety of the mixer is ensured by the static electricity eliminating device, the explosion-proof wall, the interlocking control system and the like.

Drawings

FIG. 1 is a schematic view of a construction of the present invention;

FIG. 2 is a schematic axial view of the feed zone when the layered separator of the present invention is two.

In the figure: the device comprises an A-feeding zone, a B-distribution zone, a C-jet mixing zone, a 1-barrel, a 2-ethylene inlet, a 3-layering partition plate, a 4-oxygen inlet, a 5-distribution plate, a 6-oxygen passage hole, a 7-ethylene passage hole, an 8-ethylene baffle, a 9-jet ring, a 10-ethylene annular passage and an 11-oxygen annular passage.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

Fig. 1 is a schematic view of a construction of the present invention, as shown,

the ethylene and oxygen mixer of the invention comprises a cylinder 1, a layered baffle 3, a distribution plate 5, a spray ring 9, an ethylene inlet 2 and an oxygen inlet 4; the cylinder body 1 is cylindrical, the left end is closed, and the right end is open; the spray rings 9 are cylindrical with two open ends, and the number of the spray rings 9 is six; the distribution plate 5 is fixed on the inner wall of the cylinder body 1, the left end of the spray ring 9 is welded on the distribution plate 5 along the axis of the cylinder body 1 and is coaxially arranged with the cylinder body 1, and the right end of the spray ring 9 is a free end; the space between the distribution plate 5 and the closed end, namely the left end, of the cylinder 1 forms a feeding area A, the space between the distribution plate 5 and the cylinder 1 where the spray ring 9 is positioned forms a distribution area B, and the space between the spray ring 9 and the open end, namely the right end, of the cylinder 1 forms a jet mixing area C; the layering partition plate 3 is positioned in the feeding area A, is vertically fixed on the distribution plate 5 along the axis of the cylinder body 1, divides the feeding area A into two types of ethylene feeding areas and oxygen feeding areas, and is connected with the ethylene feeding areas, and the oxygen inlet 4 is connected with the oxygen feeding areas; the distribution plate 5 and the injection ring 9 divide the distribution area B into seven annular channels with diameters from large to small along the radial direction of the cylinder 1 from outside to inside, the seven annular channels comprise four ethylene annular channels 10 and three oxygen annular channels 11, and the ethylene annular channels 10 and the oxygen annular channels 11 are alternately arranged along the radial direction of the cylinder 1 from outside to inside; ethylene channel holes 7 are formed in the distribution plate in the ethylene feeding area and correspond to the corresponding ethylene annular channels 10; the distribution plate in the oxygen feeding area is provided with oxygen channel holes 6 which correspond to the corresponding oxygen annular channels 11; in the feed zone a and distribution zone B, no feed mixing of ethylene and oxygen occurs.

The ethylene baffle plate 8 is arranged on the inner wall of the ethylene annular channel 10, which corresponds to the ethylene channel hole 7, and the height of the ethylene baffle plate 8 is smaller than the radial width of the ethylene annular channel 10, so that the flow resistance of ethylene entering the ethylene annular channel 10 is increased, the ethylene is promoted to flow to the position of the ethylene annular channel which is not directly provided with the ethylene channel hole, and the ethylene is uniformly distributed in the annular channel in a shorter distance.

Fig. 2 is a schematic axial structure of a feeding area when the number of the layered separators is two, as shown in the drawing, the number of the layered separators 3 is two, the layered separators vertically intersect, the feeding area is divided into two ethylene feeding areas and two oxygen feeding areas, the two ethylene feeding areas correspond to the two ethylene inlets 2, the two oxygen feeding areas correspond to the two oxygen inlets 4, and the ethylene feeding areas and the oxygen feeding areas are alternately arranged along the circumferential direction of the distribution plate 5. The distribution plate 5 is a circular flat plate, and is provided with an oxygen passage hole 6 and an ethylene passage hole 7. The oxygen passage holes 6 are shown in the figure with circular arc-shaped shadows having a narrow radial width, and the ethylene passage holes 7 are shown in the figure with circular arc-shaped shadows having a wide radial width. The non-perforated areas on the distribution plate 5 are non-shaded areas.

As shown in fig. 1 and 2, the present invention operates:

ethylene enters an ethylene feeding area from an ethylene inlet 2, enters an ethylene annular channel 10 through ethylene channel holes 7 on a distribution plate 5, diffuses in the ethylene annular channel 10 to an area where no ethylene directly enters, and enters a jet mixing area C after being uniformly distributed in the ethylene annular channel 10;

oxygen enters the oxygen feeding area from the oxygen inlet 4, enters the oxygen annular channel 11 through the oxygen channel holes 6 on the distribution plate 5, diffuses in the oxygen annular channel 11 to the area where no oxygen directly enters, and enters the jet mixing area C after being uniformly distributed in the oxygen annular channel 11;

in jet mixing zone C, ethylene and oxygen are jet mixed.

Claims (11)

1. An ethylene and oxygen mixer, characterized by: comprises a cylinder body, a layered partition plate, a distribution plate, a spray ring, an ethylene inlet and an oxygen inlet; the cylinder body is cylindrical, one end of the cylinder body is closed, and the other end of the cylinder body is open; the spray ring is cylindrical with two open ends; the distribution plate is fixed in the cylinder, and one end of the injection ring is fixed on the distribution plate along the axis of the cylinder and is coaxially arranged with the cylinder; the space between the distribution plate and the closed end of the cylinder forms a feeding area, the space in the cylinder where the distribution plate and the injection ring are positioned forms a distribution area, and the space between the injection ring and the open end of the cylinder forms a jet flow mixing area; the layering partition plate is positioned in the feeding area, is vertically fixed on the distribution plate along the axis of the cylinder body, divides the feeding area into an ethylene feeding area and an oxygen feeding area, and is connected with the ethylene feeding area and the oxygen feeding area; the distribution plate and the injection ring divide the distribution area into annular channels with the diameters from large to small along the radial direction of the cylinder body, the annular channels are divided into ethylene annular channels and oxygen annular channels, and the ethylene annular channels and the oxygen annular channels are alternately arranged along the radial direction of the cylinder body from outside to inside; ethylene channel holes are formed in the distribution plate in the ethylene feeding area and correspond to the corresponding ethylene annular channels; and oxygen channel holes are formed in the distribution plate in the oxygen feeding area and correspond to the corresponding oxygen annular channels.

2. The mixer according to claim 1, characterized in that: the number of the spray rings is 2-12.

3. The mixer according to claim 1, characterized in that: the number of the layered separators is 2-6.

4. The mixer according to claim 1, characterized in that: the ethylene feeding areas and the oxygen feeding areas are alternately distributed along the circumferential direction of the cylinder body.

5. The mixer according to claim 1, characterized in that: the radial width of the ethylene annular channel is greater than the radial width of the oxygen annular channel.

6. The mixer according to claim 1, characterized in that: and an ethylene baffle is arranged on the inner wall of the ethylene annular channel, which corresponds to the ethylene channel hole, and the height of the ethylene baffle is smaller than the radial width of the ethylene annular channel.

7. The mixer of claim 6, wherein: the height of the ethylene baffle is less than 1/2 of the radial width of the ethylene annular channel.

8. The mixer according to claim 1, characterized in that: the annular channel of the outermost ring of the distribution area is an ethylene annular channel.

9. A mixer according to any one of claims 1 to 8, wherein: and the device also comprises an electrostatic grounding device.

10. A mixer according to any one of claims 1 to 8, wherein: the mixer also comprises an explosion-proof wall arranged outside the mixer.

11. A mixer according to any one of claims 1 to 8, wherein: an interlock control system is also included.