CN110964555A

CN110964555A - Atomizing nozzle for lifting pipe

Info

Publication number: CN110964555A
Application number: CN201811157881.2A
Authority: CN
Inventors: 柳召永; 张忠东; 王艳飞; 曹庚振; 刘明霞; 王辰晨; 张爱群; 汪毅; 樊红超; 翟佳宁; 孙志国; 杜晓辉
Original assignee: Petrochina Co Ltd
Current assignee: Petrochina Co Ltd
Priority date: 2018-09-30
Filing date: 2018-09-30
Publication date: 2020-04-07

Abstract

The invention discloses an atomizing nozzle for a lifting pipe, which comprises a nozzle main body, wherein the nozzle main body is a two-layer sleeve composed of an inner pipe and an outer pipe, the two ends of the two-layer sleeve are respectively an inlet end and an outlet end, the inlet end of the inner pipe is positioned outside the outer pipe, and the outlet end of the inner pipe is positioned inside the outer pipe; the outlet end of the outer pipe is provided with a second nozzle head, the inlet end of the second nozzle head is connected with the outlet end of the outer pipe, the outlet end of the second nozzle head extends to the outside of the outer pipe, the cross-sectional area of the second nozzle head is gradually reduced towards the direction far away from the outer pipe, and the second nozzle head is in a cone shape; the outlet end of the inner pipe is provided with a first nozzle head, the inlet end of the first nozzle head is connected with the outlet end of the inner pipe, the outlet end of the first nozzle head is close to the outlet end of the second nozzle head, and the first nozzle head is in a circular truncated cone shape; the outer wall of the inner pipe is provided with at least one bulge.

Description

Atomizing nozzle for lifting pipe

Technical Field

The invention relates to an atomizing nozzle, in particular to an atomizing nozzle for a medium-sized lifting pipe.

Background

The feed atomizing nozzle is used to atomize the material oil and return oil into fine liquid drops and spray them into riser, where the material oil is gasified and cracked under the action of catalyst at the temperature in the riser, and then passes through a separator to separate oil, gas and solvent and enter the next process.

The common feeding atomizing nozzle consists of a mixing cavity and a spraying section. In the mixing cavity, the atomized liquid meets the auxiliary atomized steam, and the auxiliary atomized steam is sheared and torn mutually to form mutually blended two-phase flow, and then the two-phase flow is sprayed out through the spray opening of the spraying section. These nozzles basically utilize the flow stability theory of fluid dynamics to generate as large a difference in vapor (liquid) two-phase velocity as possible in the mixing chamber to achieve the purpose of tearing and breaking up the liquid, but the effect is often not ideal because the nozzles based on this principle cannot reasonably utilize the energy of the atomized vapor.

The early atomizing nozzle at home and abroad is a throat nozzle, steam is directly sprayed into liquid in a nozzle mixing cavity through a pipe, the liquid is torn through shearing between the steam and the liquid, the nozzle is a common circular jet nozzle, the atomizing effect is good, flat fan-shaped spray jet required by a catalytic cracking process cannot be generated, the average atomizing particle size is more than 80-100 mu m, and the nozzle becomes a first-generation feeding nozzle.

After improvement, the second generation of feeding nozzles are generated, such as foreign target nozzles, domestic pre-film nozzles and other nozzles, the average atomization particle size of the nozzles is kept between 60 and 80 mu m, and the aims of tearing and crushing liquid are fulfilled by needing a great speed difference between steam (gas) and liquid phases, so that great steam (gas) inlet speed is needed, and some nozzles even reach or exceed the sound speed, have higher energy consumption and can generate pulsation. If this is not achieved, the nozzle is difficult to operate normally, the atomization effect is deteriorated sharply, and the operational flexibility is also affected. These nozzles also have difficulty producing flat fan spray jets that are also difficult to produce for the catalytic cracking process.

In the nineties, foreign oil companies increased research on feed nozzles, Mobil and Kellog companies began to collaborate in 1990 to develop research work on new atomizing nozzles, and in 1994 to develop a new feed nozzle Atomax; UOP company developed a new atomizing nozzle Optimix in 1995; the nozzles adopt different steam distribution structures and different nozzle forms in a mixing cavity, and the atomization average particle size is about 60 mu m; the Shell company develops a novel feeding nozzle in 1998, and applies for an invention patent CN98192423.3 in China, the nozzle is an external mixing type feeding nozzle, steam in the nozzle is mixed with raw oil at a nozzle, and the steam is used for driving the raw oil to be sprayed out from the nozzle; the nozzle can generate flat fan-shaped spray jet required by the catalytic cracking process, and becomes a third generation novel atomized feeding nozzle. The third generation of novel atomizing nozzles all adopt primary pressure-changing intensified atomization, which is not beneficial to the uniform mixing of steam and raw oil.

Many petroleum refinery and chemical plant facilities utilize nozzles to distribute liquid and/or gaseous feedstocks to the facilities. In some plants, the performance of the nozzles that dispense the feedstock to the plant is of paramount importance to the capacity of the plant. In order to obtain optimum performance of the reactor, the nozzle must dispense the feedstock in a fine spray with uniform coverage and very small droplets. Such spraying increases the area of the feedstock droplets and facilitates contact between the feedstock droplets and the catalyst particles, however, it is difficult to achieve the desired performance with existing nozzles. Some nozzles utilize very small openings or complex head designs that are easily clogged by various impurities in the material, and the downtime and replacement costs are very disadvantageous in repairing such blockages, and existing nozzles are not capable of producing fine droplets and/or the desired spray pattern.

Disclosure of Invention

It is therefore an object of the present invention to provide an atomizing nozzle for a riser of a catalytic cracking unit, which can achieve precise distribution of fine liquid droplets, thin layer spraying, without clogging.

To this end, the present invention provides an atomizing nozzle for a riser, the atomizing nozzle including a nozzle body,

the nozzle main body is a two-layer sleeve composed of an inner tube and an outer tube, the two ends of the two-layer sleeve are respectively an inlet end and an outlet end, the inlet end of the inner tube is positioned outside the outer tube, and the outlet end of the inner tube is positioned inside the outer tube;

the outlet end of the outer pipe is provided with a second nozzle head, the inlet end of the second nozzle head is connected with the outlet end of the outer pipe, the outlet end of the second nozzle head extends to the outside of the outer pipe, the cross-sectional area of the second nozzle head is gradually reduced towards the direction far away from the outer pipe, and the second nozzle head is in a cone shape;

the outlet end of the inner pipe is provided with a first nozzle head, the inlet end of the first nozzle head is connected with the outlet end of the inner pipe, the outlet end of the first nozzle head is close to the outlet end of the second nozzle head, the first nozzle head is provided with at least one channel and at least one outlet end, the cross-sectional area of the first nozzle head is gradually reduced towards the direction far away from the inner pipe, and the first nozzle head is in a circular truncated cone shape;

the outer wall of the inner pipe is provided with at least one bulge.

Wherein, an annular liquid pipeline, namely a dispersion medium pipeline, is formed between the outer wall of the inner pipe and the inner wall of the outer pipe, and a pipeline with a reducing structure, namely a mixing cavity, is formed between the inner wall of the second nozzle head and the outer wall of the first nozzle head; the inlet end of the inner pipe is a raw oil feeding inlet, and the inlet end of the outer pipe is a dispersion medium inlet.

The atomizing nozzle for the lifting pipe is characterized in that the inner pipe and the outer pipe are both preferably cylindrical sleeves, the inner pipe and the outer pipe preferably have the same longitudinal center line, and the inner pipe and the outer pipe are preferably fixedly connected through the positioning column.

The atomizing nozzle for a riser according to the present invention, wherein the first nozzle head and the second nozzle head preferably have the same longitudinal centerline.

The lift pipe of the present invention is an atomizing nozzle, wherein the outlet end of the first nozzle head preferably protrudes into the interior of the second nozzle head.

The atomizing nozzle for the riser pipe is characterized in that the distance between the outlet end of the first nozzle head and the outlet end of the second nozzle head is preferably 0.006-0.030 m.

The atomizing nozzle for a riser according to the present invention is preferably configured such that the outlet end of the first nozzle head has a first planar structure, the outlet end of the second nozzle head has a second planar structure, and the first planar structure and the second planar structure are each provided with a plurality of holes.

The atomizing nozzle for the lifting pipe is characterized in that the number of the holes in the first planar structure is greater than or equal to that of the holes in the second planar structure, the holes are circular holes or duckbill-shaped holes, the diameter of each circular hole is 0.1-10 mm, and the length and the width of each duckbill-shaped hole are 0.1-10 mm respectively.

The atomizing nozzle for a riser according to the present invention is preferably configured such that an included angle between the inner wall of the first nozzle head and the inner wall of the inner tube is β, β is 20 ° to 85 °, an included angle between the inner wall of the second nozzle head and the inner wall of the outer tube is α, α is 30 ° to 89 °, and a sum of α and β is 90 °.

The atomizing nozzle for a riser according to the present invention is preferably one wherein α is more preferably 35 ° to 65 °, and β is more preferably 25 ° to 55 °.

The vertical section of the bulge is preferably rectangular, semicircular, semi-elliptical or semi-rhombic.

In the atomizing nozzle for a riser according to the present invention, preferably, the protrusion is located in the middle of the inner tube, and a distance between a midpoint of the protrusion and an outlet end of the inner tube is 5% to 90%, and more preferably 50% to 90%, of a distance between the inlet end and the outlet end of the inner tube.

The atomizing nozzle for the lifting pipe is characterized in that the radius of the outer pipe is preferably 0.05-0.25 m, more preferably 0.1-0.25 m, and even more preferably 0.12-0.2 m; the radius of the inner pipe is preferably 0.04-0.20 m.

The atomizing nozzle for the riser according to the present invention is preferably configured such that a thermocouple sleeve is disposed on an outer wall of the inner tube, and the thermocouple sleeve is disposed outside the outer tube and near an inlet end of the inner tube.

The riser of the present invention is used with atomizing nozzles for introducing steam formed from steam and/or hydrocarbon oil liquids into certain vessels.

Specifically, the atomizing nozzle for the riser is a feeding nozzle and can be used in a process of catalytically cracking heavy oil hydrocarbon, wherein the heavy oil hydrocarbon enters an inner pipe through a raw oil feeding inlet, enters an oil-gas guide pipe after being heated by a thermocouple sleeve and is sprayed out from a first nozzle head, meanwhile, steam enters a dispersion medium guide pipe through a dispersion medium inlet, the steam is in contact with the heavy oil hydrocarbon in a mixing cavity, the mixing cavity is of a reducing structure along the flowing direction of the steam and the hydrocarbon, so that the steam enters the hydrocarbon to form a fine two-phase mixture of steam bubbles emerging from the hydrocarbon oil mixture, the heavy oil hydrocarbon and the steam are quickly and fully mixed in the mixing cavity, meanwhile, the flow rate of the mixed material is accelerated, and finally the mixed material is sprayed out from a second atomizing nozzle.

It can be seen that the second nozzle tip is adapted to atomize the steam and heavy oil hydrocarbons substantially uniformly into the catalytic cracking reactor such that the mixture of steam and heavy oil hydrocarbons is fed into the catalytic cracking reactor; the channel on the outlet end of the gas pipeline can not be blocked, and the heavy oil raw material and the outlet end of the gas pipeline flow to form a cold-heat conversion function, so that the blockage caused by coking of the heavy oil raw material is avoided.

The feed atomizing nozzle of the present invention is suitable for use in a process of catalytically cracking heavy oil hydrocarbon, as shown in fig. 4 and 2, in which heavy oil hydrocarbon is preheated, mixed with steam, passed through the atomizing nozzle, and fed into a riser catalytic cracking reactor, then the heavy oil hydrocarbon contacts a cracking catalyst to produce light hydrocarbon and a spent catalyst coated with a coke layer, the light hydrocarbon is discharged from the reactor through a stripper to obtain oil gas, a portion of the catalyst coated with coke is fed into a regeneration reactor, and at least a portion of the coke on the spent catalyst is burned off to regenerate the catalyst and thereby produce flue gas.

Compared with the prior art, the invention has the following advantages:

(1) compared with the prior art, the outer wall of the inner pipe is provided with at least one bulge, so that the atomization rate of the outlet of the nozzle is greatly improved, oil gas molecules are more favorably sheared, the atomization of the oil gas molecules is improved, and the generation of products with low added values is reduced; in the prior art, when no bulge is arranged on the outer wall of the inner pipe, the linear velocity of oil gas of a nozzle of the lifting pipe is about 80m/s, but the invention achieves the effect of secondary pressure change by arranging the bulge on the outer wall of the inner pipe, can better improve the pressure of atomized steam, is more beneficial to shearing oil gas molecules, and further improves the atomization effect of the oil gas molecules, and the linear velocity of the nozzle of the lifting pipe can reach about 90 m/s.

(2) Compared with the prior art, the invention is simple and practical and is easy to realize.

Drawings

FIG. 1 is an atomizing nozzle provided by the present invention;

FIG. 2 is a longitudinal partial sectional view of a side-feed reactor of an atomizing nozzle;

FIG. 3 is a perspective view of an atomizing nozzle;

FIG. 4 is a longitudinal cross-sectional view of a bottom feed reactor of an atomizing nozzle;

FIG. 5 is a schematic view of a prior art nozzle.

Wherein the content of the first and second substances,

1-the second nozzle head,

101-the outlet end of the second nozzle head,

2-a raw oil feeding inlet,

21-oil and gas conduit, 22-first nozzle head,

221-the outlet end of the first nozzle head,

3-an inlet for the dispersion medium,

31-protrusions, 32-mixing chamber, 33-conduit for dispersion medium,

4-a thermocouple sleeve pipe is arranged in the cavity,

α -the angle between the second nozzle head and the inner wall of the dispersion medium conduit, β -the angle between the first nozzle head and the inner wall of the oil and gas conduit;

701-atomizing nozzle, 702-riser reactor, 703-stripper, 704 oil gas, 705 flue gas, 706-regenerator,

7021-riser wall.

Detailed Description

The following examples illustrate the invention in detail: the present example is carried out on the premise of the technical scheme of the present invention, and detailed embodiments and processes are given, but the scope of the present invention is not limited to the following examples, and the experimental methods without specific conditions noted in the following examples are generally performed according to conventional conditions.

Referring to fig. 1, the present invention provides an atomizing nozzle for a riser, which includes a nozzle body,

the nozzle main body is a two-layer sleeve composed of an inner tube 21 and an outer tube 6, the two ends of the two-layer sleeve are respectively an inlet end and an outlet end, the inlet end of the inner tube 21 is positioned outside the outer tube 6, and the outlet end of the inner tube 21 is positioned inside the outer tube 6;

the outlet end of the outer pipe 6 is provided with a second nozzle head 1, the inlet end of the second nozzle head 1 is connected with the outlet end of the outer pipe 6, the outlet end of the second nozzle head 1 extends to the outside of the outer pipe 6, the cross-sectional area of the second nozzle head 1 is gradually reduced towards the direction far away from the outer pipe 6, and the second nozzle head 1 is in a circular truncated cone shape;

the outlet end of the inner tube 21 is provided with a first nozzle head 22, the inlet end of the first nozzle head 22 is connected with the outlet end of the inner tube 21, the outlet end of the first nozzle head 22 is close to the outlet end of the second nozzle head 1, the first nozzle head 22 is provided with at least one channel and at least one outlet end, if the second nozzle head 1 is provided with two outlet ends, the first nozzle head 22 at least comprises two corresponding outlet ends, the cross-sectional area of the first nozzle head 22 is gradually reduced towards the direction far away from the inner tube, and the first nozzle head 22 is in a circular truncated cone shape;

the outer wall of the inner pipe 21 is provided with at least one protrusion 31, the longitudinal section of the protrusion 31 is rectangular, semicircular, semi-elliptical or semi-rhombic, the protrusion 31 is positioned in the middle of the inner pipe 21, and the distance between the midpoint and the outlet end of the protrusion 31 is 50% -90% of the distance between the inlet end and the outlet end.

Wherein, an annular liquid pipeline, namely a dispersion medium conduit 33 is formed between the outer wall of the inner pipe 21 and the inner wall of the outer pipe 6, and a pipeline with a reducing structure, namely a mixing cavity 32 is formed between the inner wall of the second nozzle head 1 and the outer wall of the first nozzle head 22; the inner tube 21 is an oil-gas conduit, the inlet end of the inner tube 21 is a raw oil feeding inlet, and the inlet end of the outer tube 6 is a dispersion medium inlet; the radius of the outer pipe 6 is 0.05-0.25 m, and the radius of the inner pipe 21 is 0.04-0.20 m.

In one embodiment of the invention, the radius of the outer tube 6 is 0.1m, 0.25m, 0.12m or 0.2 m.

Wherein, the outer wall of the inner tube 21 is provided with a thermocouple sleeve 4, and specifically, the thermocouple sleeve 4 is arranged outside the outer tube 6 and close to the inlet end of the inner tube 21.

Specifically, the inner tube 21 and the outer tube 6 are both cylindrical sleeves, the inner tube 21 and the outer tube 6 have the same longitudinal center line, and the inner tube 21 and the outer tube 6 are fixedly connected through a positioning column (not shown).

In one embodiment of the present invention, referring to FIG. 3, the first nozzle tip 22 and the second nozzle tip 1 have the same longitudinal centerline, the first nozzle tip 22 extends into the interior of the second nozzle tip 1, the outlet end of the second nozzle tip 1 extends outwardly beyond the outlet end of the first nozzle tip 22 by a distance, the distance between the outlet end of the first nozzle tip 22 and the outlet end of the second nozzle tip 1 is 0.006-0.030 meters, which is suitable for substantially uniformly atomizing the steam and heavy oil hydrocarbons into the catalytic cracking reactor.

Specifically, the outlet end of the first nozzle head 22 is a first planar structure 221, the outlet end of the second nozzle head 1 is a second planar structure 101, and a plurality of holes are formed in the first planar structure 221 and the second planar structure 101.

In another embodiment of the present invention, the number of the holes on the first planar structure 221 is greater than or equal to the number of the holes on the second planar structure 101, the holes are circular holes, and the diameter of the circular holes is 0.1-10 mm.

In another embodiment of the present invention, the angle between the inner wall of the first nozzle head 22 and the inner wall of the inner tube 21 is β, said β is 20 ° to 85 °, the angle between the inner wall of the second nozzle head 1 and the inner wall of the outer tube 6 is α, said α is 30 ° to 89 °, and the sum of said α and said β is 90 °.

In another embodiment of the invention, α is 35-65 °, β is 25-55 °.

In addition, the angle β between the inner wall of the first nozzle head 22 and the inner wall of the inner tube 21 and the angle α between the inner wall of the second nozzle head 1 and the inner wall of the outer tube 6 are close to each other, preferably do not differ by more than 10 °, most preferably do not differ by more than 3 °.

When the feeding atomizing nozzle works normally, heavy oil hydrocarbon enters the inner pipe 21 through the raw oil feeding inlet 2, is heated by the thermocouple sleeve 4 and then enters the oil-gas conduit 21 to be sprayed out from the first nozzle head 22, meanwhile, water vapor enters the dispersion medium conduit 33 through the dispersion medium inlet 3, the water vapor is contacted with the heavy oil hydrocarbon in the mixing cavity 32, and the mixing cavity 32 is of a reducing structure along the flowing direction of the water vapor and the hydrocarbon, so that the water vapor enters the hydrocarbon to form a fine two-phase mixture of water vapor bubbles sprayed out of the hydrocarbon oil mixture, the heavy oil hydrocarbon and the water vapor are quickly and fully mixed in the mixing cavity 32, meanwhile, the flow rate of the mixed material is accelerated, and finally the mixed material is sprayed out by the second atomizing nozzle 1.

It can be seen that the second nozzle head 1 is used to atomize the steam and heavy oil hydrocarbons into the catalytic cracking reactor substantially uniformly, so that the mixture of steam and heavy oil hydrocarbons is fed into the catalytic cracking reactor; the channels at the outlet end of the mixing chamber 32 are not blocked, and the heavy oil feedstock and the outlet end of the gas pipeline flow to form a cold-heat conversion function, so that the heavy oil feedstock is prevented from being blocked due to coking.

The feed atomizing nozzle of the present invention is suitable for use in a process of catalytically cracking a heavy oil hydrocarbon, as shown in fig. 4 and 2, in which the heavy oil hydrocarbon is preheated and mixed with steam, passes through the atomizing nozzle 701, and is fed into a riser catalytic cracking reactor 702, the heavy oil hydrocarbon is then contacted with a cracking catalyst to produce light hydrocarbons and a spent catalyst coated with a coke layer, the light hydrocarbons are discharged from the reactor through a stripper 703 to obtain an oil gas 704, a portion of the catalyst coated with coke is fed into a regeneration reactor 706, and at least a portion of the coke on the spent catalyst is burned off to regenerate the catalyst and thereby produce a flue gas 705.

One aspect of the present invention is to provide an atomizing nozzle for feeding heavy oil hydrocarbons into the riser catalytic cracking reactor 702, which is generally horizontally (as shown in fig. 4), vertically, or obliquely mounted in the riser reactor, although other orientations are possible. When the atomizing nozzle is mounted vertically, the nozzle typically extends upwardly from the bottom or inlet end of the reactor; when the atomizing nozzles are not mounted vertically, the nozzles typically extend from the riser wall 7021 at a position somewhere between vertical and horizontal (see FIG. 2), and different positioning typically requires different outlet end designs, as the desired spray pattern depends on the orientation of the nozzles. The nozzle according to the invention is suitable for all these positions and the shape of the holes in the second nozzle head 1 can thus be varied to obtain the desired spray pattern.

Typically, for vertically mounted atomizing nozzles, the holes in the second nozzle head 1 may be made square, circular, oval, slit-shaped or other non-linear shapes to form a spray suitable for a pipe.

The first nozzle head 22 is attached to the outlet end of the inner tube 21, optionally by various conventional means such as screwing or welding, which is also suitable for the connection of the second nozzle head 1 to the outer tube 6.

The second nozzle head 1 has at least one outlet, and if the second nozzle head 1 has two outlets, the first nozzle head 22 should comprise at least two open channels corresponding to the outlets of the second nozzle head 1, respectively.

Example 1

The atomizing nozzle for the riser adopted in this embodiment includes a nozzle main body, the nozzle main body is a two-layer sleeve composed of an inner tube 21 and an outer tube 6, two ends of the two-layer sleeve are respectively an inlet end and an outlet end, the inlet end of the inner tube 21 is located outside the outer tube 6, and the outlet end of the inner tube 21 is located inside the outer tube 6;

the outlet end of the outer pipe 6 is provided with a second nozzle head 1, the second nozzle head 1 is in a round table shape, the outlet end of the inner pipe 21 is provided with a first nozzle head 22, the inlet end of the first nozzle head 22 is connected with the outlet end of the inner pipe 21, the outlet end of the first nozzle head 22 is close to the outlet end of the second nozzle head 1, the distance between the outlet end of the first nozzle head 22 and the outlet end of the second nozzle head 1 is 0.020m, the first nozzle head 22 is provided with a passage and an outlet end, and the first nozzle head 22 is in a round table shape;

the outer wall of the inner tube 21 is provided with a protrusion 31, the longitudinal section of the protrusion 31 is rectangular, the protrusion 31 is located in the middle of the inner tube 21, and the distance between the midpoint of the protrusion 31 and the outlet end of the inner tube is 60% of the distance between the inlet end and the outlet end of the inner tube.

Wherein, an annular liquid pipeline, namely a dispersion medium conduit 33 is formed between the outer wall of the inner pipe 21 and the inner wall of the outer pipe 6, and a pipeline with a reducing structure, namely a mixing cavity 32 is formed between the inner wall of the second nozzle head 1 and the outer wall of the first nozzle head 22; the inner tube 21 is an oil-gas conduit, the inlet end of the inner tube 21 is a raw oil feeding inlet, and the inlet end of the outer tube 6 is a dispersion medium inlet; the outer tube 6 has a radius of 0.2m and the inner tube 21 has a radius of 0.11 m.

Specifically, the outlet end of the first nozzle head 22 is a first planar structure 221, the outlet end of the second nozzle head 1 is a second

planar structure

101, 6 holes (diameter of 1mm) are formed in the first

planar structure

221, and 4 holes (diameter of 1mm) are formed in the second planar structure 101.

The angle between the inner wall of the first nozzle head 22 and the inner wall of the inner tube 21 is β, said β is 45 °, the angle between the inner wall of the second nozzle head 1 and the inner wall of the outer tube 6 is α, said α is 45 °.

Adopt water and decompression wax oil to feed respectively, water becomes vapor and gets into vapor pipeline promptly dispersion medium pipe after the heating, and decompression wax oil gets into heavy oil annular duct promptly oil gas pipe, and the rate of feed, the feed pressure and the temperature of decompression wax oil at raw oil feedstock inlet 2 are respectively: 1.7kg/h, 0.02Mpa, 300 ℃; the feed rate, feed pressure and temperature of the water vapor at the dispersion medium inlet 3 were respectively: 4g/min, 0.02MPa, 500 ℃.

The test results are shown in Table 1.

Comparative example 1

The difference from example 1 is that the existing atomizing nozzle shown in fig. 5 is used, and the tube wall is not provided with projections, wherein β 'is 45 ° and α' is 40 °.

The test results are shown in Table 1.

TABLE 1

From table 1, it can be seen that the feed nozzle assembly of the present invention has superior performance in the experiment. Due to the addition of the mixing chamber, it is important to have a smaller droplet size for uniform dispersion and uniform contact with the catalyst, thereby avoiding non-selective reactions.

The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it is therefore intended that all such changes and modifications as fall within the true spirit and scope of the invention be considered as within the following claims.

Claims

1. An atomizing nozzle for a riser, characterized in that the atomizing nozzle comprises a nozzle body,

the outer wall of the inner pipe is provided with at least one bulge.

2. The atomizing nozzle for a riser according to claim 1, wherein the inner tube and the outer tube are both cylindrical sleeves, the inner tube and the outer tube have the same longitudinal centerline, and the inner tube and the outer tube are fixedly connected by a positioning post.

3. The atomizing nozzle for a riser of claim 1, wherein the first nozzle tip and the second nozzle tip have the same longitudinal centerline.

4. An atomizing nozzle for a riser as set forth in claim 1, wherein the outlet end of the first nozzle tip extends into the interior of the second nozzle tip.

5. The atomizing nozzle for a riser according to claim 4, wherein a distance between an outlet end of the first nozzle tip and an outlet end of the second nozzle tip is 0.006 to 0.030 m.

6. An atomizing nozzle for a riser according to claim 1, wherein the outlet end of the first nozzle tip is of a first planar configuration and the outlet end of the second nozzle tip is of a second planar configuration, the first and second planar configurations each having a plurality of apertures disposed therein.

7. The atomizing nozzle for the lifting pipe according to claim 6, wherein the number of the holes on the first planar structure is greater than or equal to the number of the holes on the second planar structure, the holes are circular holes or duckbill-shaped holes, the diameter of the circular holes is 0.1-10 mm, and the length and width dimensions of the duckbill-shaped holes are 0.1-10 mm respectively.

8. An atomizing nozzle for a riser according to claim 1, characterized in that the angle between the inner wall of the first nozzle head and the inner wall of the inner tube is β, the angle between β is 20 ° to 85 °, the angle between the inner wall of the second nozzle head and the inner wall of the outer tube is α, the angle between α ° to 89 °, and the sum of α and β is 90 °.

9. An atomising nozzle as claimed in claim 8, in which the α is 35 ° to 65 ° and the β is 25 ° to 55 °.

10. The atomizing nozzle for a riser according to claim 1, wherein the longitudinal cross-section of the protrusion is rectangular, semicircular, semi-elliptical, or semi-diamond.

11. The atomizing nozzle for a riser according to claim 1, wherein the protrusion is located at a middle portion of the inner tube, and a distance between a midpoint of the protrusion and the outlet end of the inner tube is 5% to 90% of a distance between the inlet end and the outlet end of the inner tube.

12. The atomizing nozzle for a riser according to claim 1, wherein the outer pipe has a radius of 0.05 to 0.25m, and the inner pipe has a radius of 0.04 to 0.20 m.

13. The atomizing nozzle for a riser according to claim 1, wherein a thermocouple sleeve is disposed on an outer wall of the inner tube, the thermocouple sleeve being disposed outside the outer tube and proximate to the inlet end of the inner tube.