CN109133013B - Production device and production system for adjusting density of quenching liquid in insoluble sulfur production process - Google Patents

Abstract

The invention provides a production device of insoluble sulfur, which comprises an insoluble sulfur reactor and a three-stage series cyclone separator; and a solid-liquid mixed material discharge port of the reactor, which contains the insoluble sulfur semi-finished product and the quenching liquid, is connected with a feed port of a first-stage cyclone separator of the third-stage series cyclone separator. In the production device for producing insoluble sulfur, the three-stage series cyclone separator is utilized to separate the solid-liquid mixed material containing the semi-finished product of the insoluble sulfur and the quenching liquid in density, so that the separation of the high-density quenching liquid and the low-density quenching liquid is realized, the aim of reducing and stabilizing the density of the quenching liquid is further fulfilled, and the effect of the quenching process and the quality of the insoluble sulfur product are improved. The production device provided by the invention realizes the recycling of the quenching liquid, is economic and environment-friendly, reduces the investment on raw materials, and reduces the waste liquid amount in the production process. And the equipment and the process are simple, and the method is suitable for popularization and application of industrial mass production.

Description

Production device and production system for adjusting density of quenching liquid in insoluble sulfur production process

Technical Field

The invention belongs to the technical field of IS production and preparation, relates to a production device and a production system for insoluble sulfur, and particularly relates to a production device and a production system for adjusting the density of quenching liquid in the production process of insoluble sulfur.

Background

Insoluble Sulfur (Insoluble Sulfur), abbreviated as IS, molecular formula: su, a non-toxic, flammable yellow powder, is so named because it is insoluble in carbon disulfide. IS IS transparent and amorphous elastic sulfur with chain structure obtained by heating sulfur powder to boiling (444.6 deg.C), quenching in cold water or solvent, or obtained by diluting superheated sulfur vapor with inert gas, spraying in cold water mist, and cooling to below 90 deg.C, or dissolving sulfur block in ammonia and spray drying. Most (65-95%) of sulfur is insoluble in carbon disulfide, so that it is called insoluble sulfur, and the number of sulfur atoms on molecular chain is up to above 108, and it has viscoelasticity and molecular weight distribution of high polymer, so that it is also called elastic sulfur or polymeric sulfur, and belongs to the field of inorganic high-molecular chemical raw material.

As IS has the characteristic of insolubility in rubber, the phenomena of early vulcanization and sulfur spraying are not easy to generate in rubber materials, so that the IS IS used as a high-grade accelerator and a vulcanization crosslinking agent in the rubber industry, and has the advantages of no blooming, improvement of the bonding strength among all layers of a multilayer rubber product, effective reduction of the scorching phenomenon during storage of the rubber materials and the like; and the adhesive property of the rubber compound is not damaged, so that the coating process can be eliminated, gasoline is saved, the environment is clean, and insoluble sulfur is converted into common sulfur at the vulcanization temperature to play the vulcanization effect of the sulfur on rubber. Thus, it is an essential and important raw material in the production of tires, generally for particularly important products, such as in the production of all-steel tires for automobiles.

The production process of insoluble sulfur mainly comprises a water (wet) method and a solvent method (dry method), wherein water is used as a quenching agent in the wet method, the product produced by the method has poor dispersibility, the thermal stability, especially the high thermal stability, can not meet the requirement of radial tires on the insoluble sulfur with high thermal stability, the production process has large waste water amount, and the environmental protection problem is prominent, so the solvent method is widely regarded in the industry. The process for producing insoluble sulfur by the solvent method at the present stage mainly comprises the following steps: heating and gasifying sulfur, mixing gas sulfur and quenching liquid in a reactor, contacting and quenching, generating a mixture of insoluble sulfur and quenching liquid in the reactor, and performing the procedures of curing, extracting, separating, drying and the like on the insoluble sulfur. In the mechanism, the gasified sulfur is subjected to ring opening and polymerization by an S8 ring in the quenching process to form insoluble sulfur, and the ring opening polymerization of the sulfur as the raw material and the depolymerization and ring formation of the insoluble sulfur have certain balance. Therefore, the conversion rate and stability of the insoluble sulfur are particularly important in the quenching process. Usually, gaseous sulfur and a quenching liquid are mixed in a reactor, and then the mixture is quenched to form large-particle elastomers (200 μm or more) in the reactor. The insoluble sulfur production process unit comprises the working procedures of heating (gasifying) liquid sulfur and then quenching to produce insoluble sulfur. Quenching is to rapidly cool the heated gaseous sulfur, to freeze the chemical reaction, and to rapidly fix the obtained insoluble sulfur and soluble sulfur in the quenching liquid.

Therefore, the quality of the quenching process will directly affect the yield and quality of insoluble sulfur, and how to find a more suitable production process and apparatus for insoluble sulfur, improve the quenching effect, and solve the problems existing in the production of insoluble sulfur at the present stage has become one of the problems to be solved by many hair-style manufacturers in the industry.

Disclosure of Invention

In view of the above, the technical problem to be solved by the present invention is to provide a production apparatus and a production system for insoluble sulfur, and particularly to a production apparatus for adjusting the density of a quenching liquid in the production process of insoluble sulfur.

The invention provides a production device of insoluble sulfur, which comprises an insoluble sulfur reactor and a three-stage series cyclone separator;

and a solid-liquid mixed material discharge port of the reactor, which contains the insoluble sulfur semi-finished product and the quenching liquid, is connected with a feed port of a first-stage cyclone separator of the third-stage series cyclone separator.

Preferably, in the three-stage series cyclone separator,

the low-density liquid discharge port of the first-stage cyclone separator is connected with the feed port of the second-stage cyclone separator;

the low-density liquid discharge port of the second-stage cyclone separator is connected with the feed port of the third-stage cyclone separator;

the high-density liquid discharge port of the second-stage cyclone separator is connected with the feed port of the first-stage cyclone separator;

a low-density liquid discharge port of the third-stage cyclone separator is connected with a quenching liquid feed port of the insoluble sulfur reactor;

the high-density liquid discharge port of the third-stage cyclone separator is connected with the feed port of the second-stage cyclone separator;

the high-density mixed material discharge port of the primary cyclone separator is connected with the constant temperature tank;

the upper part of the reactor is provided with a gas sulfur feeding hole and a quenching liquid feeding hole;

a Venturi tube mixer is arranged in the reactor;

the first feeding hole of the Venturi tube mixer is connected with the quenching liquid feeding hole;

and the second feeding hole of the Venturi tube mixer is connected with the gas sulfur feeding hole.

Preferably, the ratio of the diameter of the cylindrical section vortex cavity of the primary cyclone separator to the diameter of the cylindrical section vortex cavity of the secondary cyclone separator is (1.05-1.3): 1;

the ratio of the diameter of the bottom end of the conical section of the first-stage cyclone separator to the diameter of the bottom end of the conical section of the second-stage cyclone separator is (1.2-1.6): 1;

the ratio of the diameter of the cylindrical section vortex cavity of the secondary cyclone separator to the diameter of the cylindrical section vortex cavity of the tertiary cyclone separator is (1.1-1.4): 1;

the ratio of the diameter of the bottom end of the conical section of the second-stage cyclone separator to the diameter of the bottom end of the conical section of the third-stage cyclone separator is (1.4-1.6): 1;

a low-density liquid discharge port of the third-stage cyclone separator, a quenching liquid feed port of the insoluble sulfur reactor and a new quenching liquid feed source are connected;

the top end feed port of the Venturi tube mixer is a first feed port; the side feed inlet of the Venturi tube mixer is a second feed inlet;

a nozzle is arranged at one side of the top end feeding hole in the Venturi tube mixer;

the side feed inlet is positioned in a negative pressure area between the nozzle and the contraction section of the Venturi tube mixer;

the number of the side feeding openings is 2-6.

Preferably, one or more of a cutter, a filter screen, a perforated plate, a conical ball, a grating and a rotary fly cutter are arranged at the throat of the Venturi tube mixer;

the blade direction of the cutter faces the feeding direction;

the reactor is a vertical reactor;

the reactor is also internally provided with a stirring paddle and a sieve plate;

the stirring paddle is arranged below the reaction zone of the reactor and above the sieve plate;

the stirring paddle and the sieve plate are arranged in the liquid phase region;

a discharge hole is formed in the bottom of the reactor;

the aperture of the opening of the sieve plate is 5-20 mm.

Preferably, the stirring paddle comprises one or more of a two-blade inclined blade stirring paddle, a three-blade wing blade stirring paddle, a three-blade fan blade stirring paddle, an arc blade paddle stirring paddle, a curved edge inclined blade stirring paddle, a composite folding blade paddle stirring paddle and a three-blade rear tooth propeller stirring paddle;

the distance between the stirring paddle and the sieve plate is 50-100 mm;

the reactor comprises a reaction zone at the upper part in the reactor and a liquid phase zone at the lower part in the reactor;

a discharge hole at the bottom end of the Venturi tube mixer is arranged in the reaction zone;

a flushing pipeline is arranged in the reactor;

the flushing pipeline is positioned below the sieve plate; the liquid spraying direction of the flushing pipeline faces the sieve plate;

a stirring shaft is arranged in the center of the reactor along the vertical direction;

the stirring paddle is arranged on the stirring shaft.

Preferably, the number of the stirring paddles is n; the number of the sieve plates is n; the number of the flushing pipelines is n; n is 1-6;

when the number of the stirring paddles, the sieve plates and the flushing pipelines is multiple, the first stirring paddle is arranged above the first sieve plate, and the first flushing pipeline is arranged below the first sieve plate; a second stirring paddle is arranged above the second sieve plate, a second flushing pipeline is arranged below the second sieve plate, and the rest can be done in the same way;

the aperture of the opening of the single-layer sieve plate is 60 to 80 percent of the aperture of the opening of the upper-layer sieve plate;

the height of the liquid phase region is 40-50% of the height of the reactor;

the flushing pipelines are distributed in a net shape;

a spray head for spraying liquid is arranged on the flushing pipeline;

the distance between the spray head and the sieve plate is 20-60 cm;

the number of the spray heads is one or more;

the reactor further comprises a warming coil and/or a cooling coil;

the reactor comprises a conical bottom; the discharge hole is formed in the bottom end of the conical bottom.

The invention also provides an insoluble sulfur production system adopting the production device in any one of the technical schemes, which comprises the following steps:

A) feeding the semi-finished product of the insoluble sulfur produced by the insoluble sulfur reactor into a first-stage cyclone separator of a third-stage series cyclone separator for first cyclone separation to obtain a first-stage low-density recovery quenching liquid and a high-density mixed material;

B) feeding the primary low-density recovered quenching liquid into a secondary cyclone separator for secondary cyclone separation to obtain secondary low-density recovered quenching liquid and secondary high-density liquid;

C) returning the secondary high-density liquid obtained in the step to a feed inlet of a primary cyclone separator for reflux and recirculation; meanwhile, feeding the secondary low-density recovered quenching liquid obtained in the step into a third-stage cyclone separator for third cyclone separation to obtain the quenching liquid capable of being recycled and a third-stage high-density liquid;

and returning the three-stage high-density liquid obtained in the step to a feed inlet of a second-stage cyclone separator for reflux and recycling.

Preferably, the temperature of the first cyclone separation is 60-90 ℃;

the material feeding pressure of the primary cyclone separator is 0.3-0.6 Mpa;

the density of the primary low-density recovery quenching liquid is 1.4-1.5 kg/L; the density of the high-density mixed material is 1.8-1.9 kg/L;

the material feeding pressure of the secondary cyclone separator is 0.3-0.6 Mpa;

the density of the secondary low-density recovery quenching liquid is 1.3-1.4 kg/L; the density of the second-stage high-density liquid is 1.7-1.8 kg/L;

the material feeding pressure of the three-stage cyclone separator is 0.3-0.6 Mpa;

the density of the quenching liquid capable of being recycled is 1.2-1.3 kg/L; the density of the three-stage high-density liquid is 1.6-1.7 kg/L;

the insoluble sulfur reactor for producing the insoluble sulfur semi-finished product comprises the following specific steps:

1) feeding the heated and gasified gas sulfur and the quenching liquid into a production device of insoluble sulfur through a gas sulfur feed port and a quenching liquid feed port, and reacting in a reaction zone to obtain a glassy elastomer;

2) under the action of gravity, the elastomer falls into a liquid phase region, and is cured at medium temperature after passing through a stirring paddle and a sieve plate to obtain an insoluble sulfur semi-finished product.

Preferably, the temperature of the gaseous sulfur is 550-700 ℃;

the quenching liquid comprises a mixed solution of solute sulfur and a solvent, or a mixed solution of solute sulfur, a solvent and insoluble sulfur;

the pressure of the quenching liquid is 0.25-0.45 Mpa; the temperature of the quenching liquid is 40-60 ℃;

the mass ratio of the feeding amount of the quenching liquid to the feeding amount of the gas sulfur is (110-250): 1;

the step 1) is specifically as follows:

11) the method comprises the following steps of (1) passing a quenching liquid through a first feeding hole and passing heated and gasified gas sulfur through a second feeding hole through a quenching liquid feeding hole and a gas sulfur feeding hole, and feeding the gas sulfur into a venturi tube mixing reactor in the reactor for mixing to obtain a mixture;

12) the mixture obtained in the step is sprayed in a reaction zone through a discharge hole of a Venturi tube mixing reactor to react, so that a glassy elastomer is obtained;

the process of passing through the stirring paddle and the sieve plate also comprises a reverse flushing step of a flushing pipeline;

and the step A) also comprises the step of delivering the high-density mixed material into a constant-temperature tank for low-temperature curing to obtain insoluble sulfur.

Preferably, the negative pressure of the negative pressure zone at which the outlet end of the second feed inlet is positioned is-0.01 to-0.06 MPa;

the outlet pressure of the quenching liquid feed inlet is 0.3-0.6 Mpa;

the outlet pressure of the gas sulfur feed inlet is 5-50 KPa;

the reaction temperature is 80-100 ℃;

the reaction time is 0.5-1.5 s;

the flushing fluid of the back flushing is a mixed solution containing carbon disulfide, soluble sulfur and a small amount of insoluble sulfur;

the pressure of the reverse flushing is 0.3-0.5 Mpa;

the temperature of the liquid phase region is 55-80 ℃;

the low-temperature curing temperature is 40-60 ℃.

The invention provides a production device of insoluble sulfur, which comprises an insoluble sulfur reactor and a three-stage series cyclone separator; the solid-liquid mixed material discharge port of the reactor containing the insoluble sulfur semi-finished product and the quenching liquid is connected with the feed port of the first-stage cyclone separator of the third-stage series cyclone separatorAnd (6) connecting. Compared with the prior art, the invention starts with the whole process of the process, and the process for producing insoluble sulfur based on the current-stage solvent method mainly comprises the following steps: heating sulfur for gasification, quenching to produce insoluble sulfur, and curing, extracting, separating and drying the insoluble sulfur. In the mechanism, the gasified sulfur is subjected to ring opening and polymerization by an S8 ring in the quenching process to form insoluble sulfur, and the ring opening polymerization of the sulfur as the raw material and the depolymerization and ring formation of the insoluble sulfur have certain balance. Through multiple tests and test runs, the quenching agent is added, the depolymerization degree of insoluble sulfur can be reduced in the shortest time through freezing reaction, but unstable factors still exist in the quenching process and are not beneficial to continuous technological production, wherein the density of the quenching liquid is greatly changed in the quenching process to reach 1.3-1.8 kg/m³The quenching effect and the quality of insoluble sulfur are seriously affected. The method is characterized in that after gas sulfur and quenching liquid are mixed and contacted in a reactor for quenching, a mixture of insoluble sulfur, soluble sulfur and a solvent is generated in the reactor, namely a mixed material of the insoluble sulfur and the quenching liquid, particularly the soluble sulfur is dissolved in the solvent, and the density of the quenching liquid is greatly changed (1.3-1.8 kg/m) due to the influences of the temperature, the flow rate, the material composition, the property of raw material sulfur and other factors of the quenching liquid³) The quenching effect and the quality of insoluble sulfur products are seriously influenced, and the stable density of the quenching liquid is important to the quality of the insoluble sulfur products.

The invention creatively improves the production device for producing insoluble sulfur, adds the three-stage series cyclone separator, and utilizes the three-stage series cyclone separator to separate the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid in density, thereby realizing the separation of high-density and low-density quenching liquid, further achieving the purpose of reducing and stabilizing the density of the quenching liquid, and further improving the effect of the quenching process and the quality of the insoluble sulfur product. The production device provided by the invention realizes the recycling of the quenching liquid, greatly reduces the pollution or discharge of industrial waste liquid, is economic and environment-friendly, reduces the investment on raw materials, and greatly reduces the waste liquid amount in the production process.

The invention adopts special quenching equipment and quenching mode, improves the effect of the quenching process, realizes the recycling of the production waste liquid, and improves the conversion rate and stability of insoluble sulfur. And the equipment and the process are simple, economic and environment-friendly, and are suitable for popularization and application of industrial mass production.

Experimental results show that by adopting the production device and the production process of insoluble sulfur provided by the invention, after three times of separation by the hydrocyclone, the quality and the density of the quenching liquid can be controlled, and the extreme cold effect is facilitated. Meanwhile, the concentrated solution separated by the three hydrocyclones has high insoluble sulfur content (60-85 percent), thereby greatly reducing the load of subsequent separation, washing and drying.

Drawings

FIG. 1 is a schematic structural flow diagram of a three-stage series cyclone separator in an insoluble sulfur production plant provided by the present invention;

FIG. 2 is a schematic structural diagram of an insoluble sulfur production plant provided by the present invention;

FIG. 3 is a schematic diagram of a venturi mixing reactor in an insoluble sulfur production plant according to the present invention.

Detailed Description

For a further understanding of the invention, preferred embodiments of the invention are described below in conjunction with the examples, but it should be understood that these descriptions are included merely to further illustrate the features and advantages of the invention and are not intended to limit the invention to the claims.

All of the starting materials of the present invention, without particular limitation as to their source, may be purchased commercially or prepared according to conventional methods well known to those skilled in the art.

All the raw materials of the present invention are not particularly limited in purity, and the present invention IS preferably obtained in industrial purity or purity conventional in the IS production field.

All the noun expressions and acronyms of the invention belong to the conventional noun expressions and acronyms in the field, each noun expression and acronym is clearly and definitely clear in the relevant application field, and a person skilled in the art can clearly, exactly and uniquely understand the noun expressions and acronyms.

The reaction in the invention refers to the reaction of the gas sulfur, but not the reaction of the gas sulfur and the quenching liquid. The quenching liquid is used as a quenching agent of the gas sulfur, and the generation of the self-depolymerization reaction of the gas sulfur is reduced.

The invention provides a production device of insoluble sulfur, which comprises an insoluble sulfur reactor and a three-stage series cyclone separator;

and a solid-liquid mixed material discharge port of the reactor, which contains the insoluble sulfur semi-finished product and the quenching liquid, is connected with a feed port of a first-stage cyclone separator of the third-stage series cyclone separator.

The invention has no special restriction on the specific selection of the reactor in principle, and a person skilled in the art can select and adjust the reactor according to the actual production condition, the raw material condition and the product requirement. The vertical reactor of the present invention is a vertical reactor as compared with a horizontal reactor.

The definition and the mode of the connection are not particularly limited in the present invention, and the definition and the mode of the connection are well known to those skilled in the art, and can be selected and adjusted by those skilled in the art according to the actual production situation, the raw material situation and the product requirement, and the connection in the present invention preferably includes a direct fixed connection or a connection through a pipeline, and more preferably, a connection through a pipeline. In the present invention, various corresponding metering and control devices are also within the technical scheme of the present invention, and those skilled in the art can select and adjust the metering and control devices according to the actual production conditions, raw material conditions and product requirements.

The type and selection of the cyclone separator are not particularly limited, and the cyclone separator known to those skilled in the art can be selected and adjusted according to actual production conditions, raw material conditions and product requirements.

In the invention, a discharge hole of a solid-liquid mixed material containing an insoluble sulfur semi-finished product and quenching liquid of the reactor is connected with a feed hole of a first-stage cyclone separator of the three-stage series cyclone separator. The method has the effects of realizing the preliminary separation of mixed materials produced by the reactor, the solid-liquid separation and the effective separation of high-density liquid and low-density liquid, thereby realizing the cyclic utilization of the quenching liquid and improving the quality of insoluble sulfur. Meanwhile, the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid can also realize the low-temperature curing process in the primary cyclone separation process.

In the three-stage series cyclone separator, a low-density liquid discharge port of the first-stage cyclone separator is preferably connected with a feed inlet of the second-stage cyclone separator. The method has the function that after primary solid-liquid separation, the separated liquid phase is continuously subjected to secondary separation.

The low-density liquid discharge port of the second-stage cyclone separator is preferably connected with the feed port of the third-stage cyclone separator; and the high-density liquid discharge port of the second-stage cyclone separator is preferably connected with the feed port of the first-stage cyclone separator. The method has the effects that after the primary separation of the second-level high-low density liquid, the separated liquid phase is subjected to the fine separation of the third-level high-low density liquid. Meanwhile, the high-density liquid separated out in the second stage flows back to the first-stage cyclone separator again, so that the solid-liquid separation and the full circulation of a separation system are realized again.

The low-density liquid discharge port of the third-stage cyclone separator is preferably connected with the quenching liquid feed port of the insoluble sulfur reactor; the high-density liquid discharge port of the third-stage cyclone separator is preferably connected with the feed port of the second-stage cyclone separator; the method has the effects that after three-stage high-low density liquid is finely separated, the separated low density liquid phase can be used as circulating quenching liquid to enter an insoluble sulfur reactor, and the reutilization of the quenching liquid is realized. Meanwhile, the high-density liquid separated out in the third stage flows back to the second-stage cyclone separator again, so that the primary separation of the high-density liquid and the low-density liquid again and the full circulation of a separation system are realized.

In order to further improve the effect of three-stage series separation, the three-stage series cyclone separator is particularly preferably a three-stage stepped series cyclone separator, namely the selection of the cyclone separator is gradually reduced according to a specific proportion, so that high-density and low-density stepped separation is realized, the density of the final circulating quenching liquid is low and stable, and the density can be adjusted according to actual production.

The ratio of the diameter of the cylindrical section vortex cavity of the primary cyclone separator to the diameter of the cylindrical section vortex cavity of the secondary cyclone separator is preferably (1.05-1.3): 1, more preferably (1.1 to 1.25): 1, more preferably (1.15 to 1.2): 1.

in order to better improve the effect of three-stage series separation and realize high-low density step separation, the density of the final circulating quenching liquid is low and stable, and the density can be adjusted according to actual production, wherein the ratio of the diameter of the conical section bottom end of the first-stage cyclone separator to the diameter of the conical section bottom end of the second-stage cyclone separator is preferably (1.2-1.6): 1, more preferably (1.25 to 1.55): 1, more preferably (1.3 to 1.5): 1, more preferably (1.35 to 1.45): 1. the ratio of the diameter of the cylindrical section vortex cavity of the secondary cyclone separator to the diameter of the cylindrical section vortex cavity of the tertiary cyclone separator is preferably (1.1-1.4): 1, more preferably (1.15 to 1.35): 1, more preferably (1.2 to 1.3): 1. the ratio of the diameter of the bottom end of the conical section of the second-stage cyclone separator to the diameter of the bottom end of the conical section of the third-stage cyclone separator is preferably (1.4-1.6): 1, more preferably (1.42 to 1.58): 1, more preferably (1.45 to 1.55): 1, more preferably (1.47 to 1.53): 1.

in order to better realize the functions of recycling the quenching liquid and partial low-temperature curing, ensure the quality of insoluble sulfur of a final product and meet the process requirement of continuous production, the device is integrated and refined, and a high-density mixed material discharge port of the primary cyclone separator is preferably connected with a constant-temperature tank. The method has the function that the high-density mixed material enters a constant-temperature tank to carry out the subsequent low-temperature curing process, so that the integral curing process of the insoluble sulfur is completed.

In the invention, the low-density liquid discharge port of the three-stage cyclone separator, the quenching liquid feed port of the insoluble sulfur reactor and a new quenching liquid feed source (feed pipeline) are preferably connected, namely, the low-density liquid (capable of recycling the quenching liquid) treated by the cyclone separator can be added with new quenching liquid for density adjustment. More specifically, but the cyclic utilization quench liquid that tertiary cyclone's material separation came out, the pipeline can also be equipped with mass flow meter, can supply fresh quench liquid before the flowmeter simultaneously, can realize chain, automatic control, and the density of the final circulation quench liquid of better realization is low and stable, can also carry out density according to actual production and adjust.

The invention provides a production device of insoluble sulfur, which is characterized in that a three-stage series cyclone separator is added on the basis of an insoluble sulfur reactor, and the three-stage series cyclone separator is utilized to separate the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid in density, so that the separation of the high-density quenching liquid and the low-density quenching liquid is realized, the purpose of reducing and stabilizing the density of the quenching liquid is further achieved, and the effect of the quenching process and the quality of the insoluble sulfur product are improved. Specifically, the discharge of the insoluble sulfur synthesis reactor is lifted to a first-stage cyclone separator by a pump, so that first-stage centrifugation and cyclone separation of the materials are realized, and the separated materials are divided into two paths: one path enters a secondary rotational flow splitter, and the other path enters a subsequent process, namely constant-temperature low-temperature curing; the material entering the secondary separator is subjected to secondary centrifugation and cyclone separation, and the separated material is divided into two paths: one path enters a third-stage cyclone flow divider, and the other path enters an inlet of a first-stage cyclone separator. The material entering the three-stage separator is subjected to three-stage centrifugation and cyclone separation, and the separated material is divided into two paths: one path enters the inlet of the second-stage cyclone separator as the quenching liquid, and the other path enters the inlet of the second-stage cyclone separator, so that the low-density quenching liquid is adjusted. The production device provided by the invention realizes the recycling of the quenching liquid, greatly reduces the pollution or discharge of industrial waste liquid, is economic and environment-friendly, reduces the investment on raw materials, and greatly reduces the waste liquid amount in the production process. The production process of the invention adopts the principle of setting three-stage cyclone separation to realize the separation of high-density and low-density quenching liquid, and then combines with the supplement of fresh quenching liquid to supplement the circulating quenching liquid, thereby achieving the purposes of better reducing and stabilizing the density of the quenching liquid.

Referring to fig. 1, fig. 1 is a schematic structural flow diagram of a three-stage series cyclone separator in an insoluble sulfur production device provided by the invention. Wherein, 1 is first feed inlet, 2 is the fastener, 3 is the gland, 4 is the nozzle, 5 is the second feed inlet, 6 is negative pressure chamber (negative pressure zone), 7 is mixing chamber (mixing zone), 8 is the cutter of choke department, 9 is the discharge gate. 1 is one-level cyclone, 2 is second grade cyclone, 3 is tertiary cyclone, 4 and 5 are the intermediate pump, 6 is mass flow meter, 7 is the feed inlet, 8 is one-level low density liquid discharge gate, 9 is high density mixture discharge gate, 10 is second grade low density recovery quench liquid discharge gate, 11 is second grade cyclone feed inlet, 12 is second grade high density liquid discharge gate, 13 is circulated utilization's quench liquid discharge gate, 14 is tertiary cyclone feed inlet, 15 is fresh quench liquid feed department, 16 is circulated utilization's quench liquid and the mixed liquid discharge gate of new quench liquid (is connected with the quench liquid feed inlet of the vertical reactor in the apparatus for producing insoluble sulphur).

In order to better realize the reaction process of the insoluble sulfur reactor, control the particle size of an intermediate product, namely an elastomer, and finish medium-high temperature curing, ensure the thermal stability of a final product, ensure the normal passing rate and meet the process requirement of continuous production, the upper part of the insoluble sulfur reactor is preferably provided with a gas sulfur feed port and a quenching liquid feed port; the reactor is preferably internally provided with a stirring paddle and a sieve plate, and the stirring paddle is preferably arranged below the reaction zone of the vertical reactor and above the sieve plate. Meanwhile, the bottom of the reactor is preferably provided with a discharge hole.

In the invention, the upper part of the vertical reactor is provided with a gas sulfur feeding hole and a quenching liquid feeding hole. The vertical reactor has the advantages that the feeding is convenient, and the quenching reaction of the gas sulfur is carried out by utilizing the vertical space characteristics and the gravity factor of the vertical reactor. The specific positions of the gas sulfur feed inlet and the quenching liquid feed inlet are not particularly limited in the present invention, and the feed inlets of the conventional vertical reactor, which are well known to those skilled in the art, may be arranged, and those skilled in the art may select and adjust the feed inlets according to the actual production conditions, raw material conditions and product requirements.

In the invention, a stirring paddle and a sieve plate are arranged in the vertical reactor, and the stirring paddle is arranged below a reaction zone of the vertical reactor and above the sieve plate. The method has the effects that the quenching reaction of the gas sulfur is carried out based on the vertical space characteristics and the gravity factors of the vertical reactor, and the particle size of the elastomer generated by the reaction is controlled below the reaction zone.

The invention has no special limitation on the aperture of the opening of the sieve plate in principle, and a person skilled in the art can select and adjust the aperture according to the actual production condition, the raw material condition and the product requirement, in order to better realize the particle size control of the elastomer, prevent the particles from being overlarge and better ensure the thermal stability of the final product, the aperture of the opening of the sieve plate is preferably 5-20 mm, more preferably 7-18 mm and more preferably 10-15 mm.

The invention has no special restriction on the specific selection of the stirring paddle in principle, and the skilled person in the art can select and adjust the stirring paddle according to the actual production condition, the raw material condition and the product requirement, in order to better realize the particle size control of the elastomer and ensure the thermal stability of the final product, the normal passing rate can be ensured, and the process requirement of continuous production can be met, the stirring paddle preferably comprises one or more of two-blade inclined paddle stirring paddles, three-blade wing-shaped paddle stirring paddles, three-blade fan-shaped paddle stirring paddles, arc-blade paddle stirring paddles, curved-edge inclined paddle stirring paddles, composite folding paddle stirring paddles and three-blade rear-tooth propeller stirring paddles, and more preferably comprises two-blade inclined paddle stirring paddles, three-blade wing-shaped paddle stirring paddles, three-blade fan-shaped paddle stirring paddles, arc-blade paddle stirring paddles, curved-edge inclined paddle stirring paddles, composite folding paddle stirring paddles or three-blade rear-tooth propeller stirring paddles.

The distance between the stirring paddle and the sieve plate is not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements.

In the present invention, the stirring paddle is preferably disposed below the reaction zone of the vertical reactor and above the sieve plate, whereas in the vertical reactor of the present invention, the reaction zone in the upper part of the vertical reactor and the liquid phase zone in the lower part of the vertical reactor are included during the reaction. Moreover, in the present invention, the elastomer produced in the reaction zone can be subjected to a medium-high temperature aging step during the falling process and the sinking process into the liquid phase zone.

The ratio of the reaction zone and the liquid phase zone is not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements, in order to better realize the particle size control of the elastomer and the completion of medium-high temperature curing, ensure the thermal stability of the final product, ensure the normal passing rate and meet the process requirements of continuous production, and the height of the liquid phase zone is preferably 40-50% of the height of the vertical reactor, more preferably 42-48%, and more preferably 44-46%.

In order to better realize the particle size control of the elastomer, ensure the thermal stability of the final product, ensure the normal passing rate and meet the process requirement of continuous production, the stirring paddle and the sieve plate are preferably arranged in a liquid phase region. The specific arrangement positions of the stirring paddle and the sieve plate are not particularly limited, and the skilled person can select and adjust the stirring paddle and the sieve plate according to the actual production condition, the raw material condition and the product requirement.

In order to better utilize the vertical space characteristics and gravity factors of the vertical reactor, realize uniform control of the particle size of the elastomer, prevent overlarge particles, ensure the thermal stability of a final product, ensure the normal passing rate and meet the process requirements of continuous production, a stirring shaft is preferably arranged at the center in the vertical reactor along the vertical direction, and the stirring paddle is preferably arranged on the stirring shaft. Meanwhile, the key point of the present invention is that the number of the stirring paddles in the present invention may be one, multiple, and more preferably multiple.

In order to better realize the particle size control of the elastomer, ensure the thermal stability of the final product, ensure the normal passing rate and meet the process requirements of continuous production, the invention integrates and refines the device, and a flushing pipeline is preferably arranged in the vertical reactor.

The washing pipeline is arranged, and has the functions of preventing elastomers clamped in sieve pores of the filtering sieve plate from blocking the sieve pores, ensuring the normal passing rate and the medium-high temperature curing process, meeting the process requirements of continuous production and reducing the size of elastomer particles produced. The flushing pipeline is preferably positioned below the sieve plate, and the liquid spraying direction of the flushing pipeline preferably impacts the sieve plate.

The invention has no special limitation on the arrangement mode of the flushing pipelines in principle, and the technicians in the field can select and adjust the flushing pipelines according to the actual production condition, the raw material condition and the product requirement. Furthermore, in order to better realize the spray cleaning of the screen, the flushing pipeline is preferably provided with a spray head for spraying liquid.

The invention has no special restriction on the selection and arrangement mode of the spray heads in principle, and the spray heads can be selected and adjusted by the technical personnel in the field according to the actual production condition, the raw material condition and the product requirement. The direction of the spray head is vertically arranged on the branch pipe, so that the spray direction of the flushing pipeline is towards the sieve plate. The diameter of the spray head is preferably 5-25 mm, more preferably 8-22 mm, more preferably 10-20 mm, and more preferably 12-18 mm.

The distance between the spray nozzle and the sieve plate is not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements, the distance between the spray nozzle and the sieve plate is preferably 20-60 cm, more preferably 25-55 cm, more preferably 30-50 cm, and more preferably 35-45 cm, so that the uniform control of the particle size of an elastomer is better realized, the thermal stability of a final product is ensured, the normal passing rate can be ensured, and the process requirement of continuous production is met. The number of the nozzles is not particularly limited, and those skilled in the art can select and adjust the nozzles according to actual production conditions, raw material conditions and product requirements.

In the present invention, the above steps provide a preferred combination of paddles, screens and flushing lines. The invention better utilizes the vertical space characteristics and gravity factors of the vertical reactor, realizes uniform control of the particle size of the elastomer, prevents overlarge particles, ensures the thermal stability of the final product, can ensure the normal passing rate, and meets the process requirements of continuous production. In the invention, n is preferably 1-6, more preferably 2-5, and more preferably 3-4. The number of the stirring paddles is preferably n; the number of the sieve plates is preferably n; the number of the flushing pipelines is preferably n.

In the invention, when the number of the stirring paddles, the sieve plates and the flushing pipelines is multiple, the first stirring paddle is arranged above the first sieve plate, and the first flushing pipeline is arranged below the first sieve plate; a second stirring paddle is arranged above the second sieve plate, a second flushing pipeline is arranged below the second sieve plate, and the like. Namely, multi-stage sieving filtration and shearing of the process intermediate, namely the elastomer are realized. In order to better utilize the vertical space characteristics and gravity factors of the vertical reactor, the invention realizes uniform control of the particle size of the elastomer, prevents overlarge particles, ensures the thermal stability of a final product, can ensure the normal passing rate and meets the process requirements of continuous production, and each set of combined stirring paddle form can be selected and can be different, more importantly, the aperture of the opening of the single-layer sieve plate is preferably 60-80% of the aperture of the opening of the upper sieve plate, more preferably 62-78%, more preferably 65-75%, and more preferably 67-73%.

The device can realize multi-section screening, filtering and shearing of the process intermediate, namely the elastomer, and can also realize step processing and control, thereby greatly improving the process throughput and better meeting the process requirements of continuous large-scale production.

The production device of insoluble sulfur provided by the steps of the invention firstly adopts the vertical reactor, realizes the continuous production process of insoluble sulfur, and utilizes the advantage of the vertical reactor in height to realize the medium-high temperature curing process in the liquid phase region; more set up stirring rake and sieve in the specific position of reactor, this important composite set for elastomer after the quenching filters through the sieve at the unloading in-process, and too big elastomer granule is by the sieve separation after, can also reduce the particle diameter through the shearing and the stirring effect of stirring rake, and then can reach the purpose that reduces the size of elastomer through the sieve. Meanwhile, the stirring paddle can adjust the stirring and shearing rotating speed at any time according to the characteristics of the materials, so that the comprehensive control of different working conditions is achieved. The invention further preferably arranges a flushing pipeline, and the backflow quenching liquid is used for flushing the filtering sieve plate to prevent the filtering sieve plate from being blocked and reduce the size of elastomer particles. The sieve plate and the backflow quenching liquid provided by the invention are combined by scouring and stirring and crushing, and then the multiple functions of a plurality of sets of combinations arranged in a stepped manner are combined, so that the purposes of reducing the size of the glassy elastomer and preventing the sieve plate from being blocked are effectively achieved, the thermal stability of a final product is improved, the normal passing rate is improved, the technological requirements of continuous production are met, and the yield of a target product is improved. The invention solves the problems that the elastomer in the prior art is too large or uneven in particle size, so that the subsequent elastomer is long in curing time, the elastomer is incompletely cured due to the inclusion of a large amount of carbon disulfide and soluble sulfur, the product quality is seriously affected, and the reaction is discontinuous and the production is low due to frequent feeding and cutting.

The vertical reactor is provided with a stirring shaft, the stirring shaft is provided with a plurality of layers of blades, a main shaft and a filter sieve plate form effective support, a tank body is provided with a sulfur raw material feeding hole, and the quenching liquid feeding hole, the quenching liquid and the sulfur are subjected to effective quenching and mixing by adopting special equipment. The tank body is internally provided with a plurality of layers of filtering sieve plates which are round and are connected with the tank body through bolts and are close to the wall of the tank, and the lower parts of the filtering sieve plates are provided with flushing pipes, flushing nozzles and the like. The invention arranges a plurality of layers of round filtering sieve plates in the reactor, and the rotating speed of the stirrer can be adjusted at any time through the shearing of the stirrer and according to the characteristics of materials, and the filtering of the sieve plates achieves the purpose of reducing the size of the elastomer. Meanwhile, the inner cone rotating spray heads are additionally arranged at the lower parts of the multi-layer circular filter sieve plates, each branch pipe spray head is provided with a pressure gauge and a flow meter and used for controlling the flow velocity of the spray heads, and the purpose of preventing the filter sieve plates from being blocked is achieved through the scouring force of the spray heads, and meanwhile, the function of adjusting the reaction time can be achieved to a certain extent.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an insoluble sulfur production apparatus provided by the present invention. Wherein, 1 is vertical reactor, 2 is the motor, 3 is the speed reducer, 4 is the (mixing) shaft, 5 is the sieve, 6 is the flushing line, 7 is the stirring rake blade, 8 is the sieve mesh, 9 is the nozzle.

In order to better improve the conversion rate and stability of the insoluble sulfur and reduce the depolymerization of the insoluble sulfur by freezing reaction in the shortest time, the reactor is preferably internally provided with a Venturi tube mixing reactor serving as a special gas-liquid mixer so as to achieve the aim of instantly reducing the temperature of gasified sulfur.

In the present invention, the first feeding port of the venturi tube mixing reactor is preferably connected to the quenching liquid feeding port; the second feeding hole of the Venturi tube mixing reactor is preferably connected with the gas sulfur feeding hole. In order to better utilize the space characteristics, pressure and reducing factors of the Venturi tube mixing reactor and realize better mixing reaction of gas sulfur and quenching liquid, a feeding hole at the top end of the Venturi tube mixing reactor is preferably a first feeding hole; the side feed of the venturi mixing reactor is preferably the second feed.

In the present invention, the top feed inlet is preferably provided with a nozzle at one side in the venturi tube mixing reactor. And the side feed inlet is positioned in a negative pressure area between the nozzle and the contraction section of the Venturi tube mixing reactor. The number of the side feeding ports is preferably 2-6, more preferably 3-5, more preferably 3-4, and most preferably 3, namely three paths of gas sulfur feeding. The method has the effects that the quenching liquid in the Venturi tube mixing reactor enters the quenching mixer in a high-pressure mode, the quenching liquid is sprayed out in the quenching mixer in a high-speed atomizing nozzle mode, a negative pressure area is formed in a subsequent air suction chamber, sulfur (gas and liquid) is sucked into the negative pressure area in one way or multiple ways at certain pressure, is in high-intensity contact and mixing with the quenching liquid, enters the mixing chamber again for contact and mixing, is cut by a cutter at certain pressure and then is sprayed to a liquid phase area of the synthesis reactor. The high-efficiency mixing of the quenching liquid and the sulfur (gas and liquid) is realized, and the purposes of uniform mixing of rapid cooling of the sulfur (gas and liquid) and limitation of self-depolymerization reaction are achieved.

The specific internal structure of the venturi tube mixing reactor is not particularly limited in principle, and may be a conventional structure of a venturi tube reactor or a venturi tube mixer well known to those skilled in the art, and those skilled in the art can select and adjust the specific internal structure according to actual production conditions, raw material conditions and product requirements.

The specific arrangement method of the cutter is not particularly limited, and a person skilled in the art can select and adjust the cutter according to the actual production condition, the raw material condition and the product requirement.

The invention has no special restriction on the specific setting position of the Venturi tube mixing reactor in principle, and a person skilled in the art can select and adjust the Venturi tube mixing reactor according to the actual production condition, the raw material condition and the product requirement.

The invention better utilizes the vertical space characteristics and gravity factors of the vertical reactor, realizes uniform control of the particle size of the elastomer, prevents overlarge particles, ensures the thermal stability of a final product, can ensure the normal passing rate, meets the process requirements of continuous production, and completely and thins equipment arrangement. The bottom of the reactor is preferably provided with a discharge port, and further, the vertical reactor preferably comprises a conical bottom, and the discharge port is preferably arranged at the bottom end of the conical bottom, so that a solid-liquid mixture of an intermediate and a quenching liquid obtained by the reaction of the reactor can be conveniently discharged. In order to better improve the conversion rate and stability of the insoluble sulfur, the invention can freeze and react in the shortest time, and increases the quenching intensity and quenching effect so as to reduce the depolymerization of the insoluble sulfur.

The production device of insoluble sulfur provided by the steps of the invention preferably adopts a vertical reactor, realizes the continuous production process of insoluble sulfur, and utilizes the advantage of the vertical reactor in height to realize the medium-high temperature curing process in the liquid phase region; the venturi tube mixing reactor is arranged at the specific position of the reactor, and the important reaction and mixing device utilizes the characteristics of the venturi tube, so that the gas sulfur and the quenching liquid are forcibly mixed, the effect of the quenching mixing reaction is greatly improved, and the depolymerization reaction of the gas sulfur is reduced.

The invention further adopts the way that the top end is provided with the quenching liquid and enters the Venturi tube mixing reactor in a high-pressure way, the quenching liquid is sprayed out in the Venturi tube mixing reactor in a high-speed atomizing nozzle way, a negative pressure area is formed in the subsequent air suction chamber, the sulfur (gas and liquid) is sprayed in at a certain pressure and then is combined with the negative pressure of the negative pressure area, so the quenching liquid can be in high-intensity contact and mixing with the quenching liquid, and the quenching liquid and the sulfur (gas and liquid) are sprayed into the reaction area of the reactor after being in contact and mixed again in the mixing chamber and being cut by a cutter in a certain pressure, thereby realizing the high-efficiency mixing of the quenching liquid and the sulfur (gas and liquid), rapidly cooling the sulfur (gas and liquid), achieving the purpose of instantly reducing the temperature of the gasified sulfur, effectively reducing the occurrence of the depolymerization reaction of the insoluble sulfur, and greatly improving the conversion rate and the thermal stability of the final product. The invention adopts special quenching equipment, has simple equipment, is easy to realize and is suitable for popularization and application of industrial mass production.

Referring to fig. 3, fig. 3 is a schematic structural diagram of a venturi mixing reactor in an insoluble sulfur production plant according to the present invention. Wherein, 1 is first feed inlet, 2 is the fastener, 3 is the gland, 4 is the nozzle, 5 is the second feed inlet, 6 is negative pressure chamber (negative pressure zone), 7 is mixing chamber (mixing zone), 8 is the cutter of choke department, 9 is the discharge gate.

The invention also provides an insoluble sulfur production system adopting the production device in any one of the technical schemes, which comprises the following steps:

A) feeding the semi-finished product of the insoluble sulfur produced by the insoluble sulfur reactor into a first-stage cyclone separator of a third-stage series cyclone separator for first cyclone separation to obtain a first-stage low-density recovery quenching liquid and a high-density mixed material;

B) feeding the primary low-density recovered quenching liquid into a secondary cyclone separator for secondary cyclone separation to obtain secondary low-density recovered quenching liquid and secondary high-density liquid;

C) returning the secondary high-density liquid obtained in the step to a feed inlet of a primary cyclone separator for reflux and recirculation; meanwhile, feeding the secondary low-density recovered quenching liquid obtained in the step into a third-stage cyclone separator for third cyclone separation to obtain the quenching liquid capable of being recycled and a third-stage high-density liquid;

and returning the three-stage high-density liquid obtained in the step to a feed inlet of a second-stage cyclone separator for reflux and recycling.

The selection and connection relationship of the devices required in the insoluble sulfur production system and the corresponding preferred principle of the invention can be corresponding to the selection and connection relationship and the corresponding preferred principle of the insoluble sulfur production device, and are not described in detail herein.

The method comprises the steps of firstly, feeding an insoluble sulfur semi-finished product produced by an insoluble sulfur reactor into a first-stage cyclone separator of a three-stage series cyclone separator, and carrying out first cyclone separation to obtain a first-stage low-density recovery quenching liquid and a high-density mixed material.

In order to further improve the effect of three-stage series separation, the three-stage series cyclone separation is particularly preferably three-stage stepped series cyclone separation, so that high-density and low-density stepped separation is realized, the density of the final circulating quenching liquid is low and stable, and the density can be adjusted according to actual production.

The method comprises the steps of firstly, feeding an insoluble sulfur semi-finished product produced by an insoluble sulfur reactor into a first-stage cyclone separator of a three-stage series cyclone separator, and carrying out first cyclone separation to obtain a first-stage low-density recovery quenching liquid and a high-density mixed material.

According to the invention, the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid produced by the reactor is subjected to first cyclone separation, so that the primary separation, the solid-liquid separation and the effective separation of high-density liquid and low-density liquid of the mixed material produced by the reactor are realized, and the recycling of the quenching liquid is realized and the quality of the insoluble sulfur is improved. Meanwhile, the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid can also realize the low-temperature curing process in the primary cyclone separation process.

The specific conditions of the first cyclone separation are not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements, in order to better realize the solid-liquid separation of mixed materials and the effective separation of high-density liquid and low-density liquid, particularly the low-temperature curing process, the temperature of the first cyclone separation is preferably 60-90 ℃, more preferably 65-85 ℃, and more preferably 70-80 ℃. The material feeding pressure of the primary cyclone separator, namely the feeding pressure of the primary cyclone separation, is preferably 0.3-0.6 Mpa, more preferably 0.35-0.55 Mpa, and more preferably 0.4-0.5 Mpa. After the first cyclone separation, the primary low-density recovery quenching liquid and the high-density mixed material are obtained, wherein the density of the primary low-density recovery quenching liquid is preferably 1.4-1.5 kg/L, more preferably 1.42-1.48 kg/L, and more preferably 1.44-1.46 kg/L. The density of the high-density mixed material is preferably 1.8-1.9 kg/L, more preferably 1.82-1.88 kg/L, and more preferably 1.84-1.86 kg/L.

The first-stage low-density recovery quenching liquid is sent to a second-stage cyclone separator for second cyclone separation, so that second-stage low-density recovery quenching liquid and second-stage high-density liquid are obtained.

The specific conditions of the second cyclone separation are not particularly limited in principle, and those skilled in the art can select and adjust the conditions according to actual production conditions, raw material conditions and product requirements, in order to better realize the solid-liquid separation of the mixed material and the effective separation of high-density and low-density liquids, the material feeding pressure of the second cyclone separator, i.e. the feeding pressure of the second cyclone separation, is preferably 0.3-0.6 Mpa, more preferably 0.35-0.55 Mpa, and more preferably 0.4-0.5 Mpa. After the second cyclone separation, a secondary low-density recovery quenching liquid and a secondary high-density liquid are obtained, wherein the density of the secondary low-density recovery quenching liquid is preferably 1.3-1.4 kg/L, more preferably 1.32-1.38 kg/L, and more preferably 1.34-1.36 kg/L. The density of the second-level high-density liquid is preferably 1.7-1.8 kg/L, more preferably 1.72-1.78 kg/L, and more preferably 1.74-1.76 kg/L.

The specific conditions of the third cyclone separation are not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements, in order to better realize the solid-liquid separation of the mixed material and the effective separation of high-density and low-density liquids, the material feeding pressure of the third cyclone separator, namely the feeding pressure of the third cyclone separation, is preferably 0.3-0.6 Mpa, more preferably 0.35-0.55 Mpa, and more preferably 0.4-0.5 Mpa. After the third cyclone separation, the recyclable quenching liquid and the three-stage high-density liquid are obtained, wherein the density of the recyclable quenching liquid is preferably 1.2-1.3 kg/L, more preferably 1.22-1.28 kg/L, and more preferably 1.24-1.26 kg/L. The density of the three-stage high-density liquid is preferably 1.6-1.7 kg/L, more preferably 1.62-1.68 kg/L, and more preferably 1.64-1.66 kg/L.

In order to better realize the functions of recycling the quenching liquid and partial low-temperature curing, ensure the quality of insoluble sulfur of a final product, meet the process requirement of continuous production, complete and refine the preparation process, the step A) further comprises the step of feeding the high-density mixed material into a constant-temperature tank for low-temperature curing to obtain the insoluble sulfur. The invention enters the high-density mixed material into the constant-temperature tank to carry out the subsequent low-temperature curing process, thereby completing the integral curing process of the insoluble sulfur.

The specific conditions of the low-temperature curing are not particularly limited in principle, and a person skilled in the art can select and adjust the conditions according to actual production conditions, raw material conditions and product requirements, in order to better ensure the quality of insoluble sulfur in a final product, the temperature of the low-temperature curing is preferably 40-60 ℃, more preferably 42-58 ℃, more preferably 45-55 ℃, and more preferably 48-52 ℃.

In the invention, the low-density liquid of the three-stage cyclone separator, namely the recyclable quenching liquid, can be directly fed into the insoluble sulfur reactor to be used as the quenching liquid.

In order to better realize the reaction process of the insoluble sulfur reactor, control the particle size of the intermediate product, namely the elastomer, and finish medium-high temperature curing, ensure the thermal stability of the final product, ensure the normal passing rate, meet the process requirements of continuous production, and complete and refine the whole process flow, the specific steps of the insoluble sulfur reactor for producing the insoluble sulfur semi-finished product are preferably as follows:

1) feeding the heated and gasified gas sulfur and the quenching liquid into a production device of insoluble sulfur through a gas sulfur feed port and a quenching liquid feed port, and reacting in a reaction zone to obtain a glassy elastomer;

2) under the action of gravity, the elastomer falls into a liquid phase region, and is cured at medium temperature after passing through a stirring paddle and a sieve plate to obtain an insoluble sulfur semi-finished product.

The invention firstly feeds the heated and gasified gas sulfur and the quenching liquid into a production device of insoluble sulfur through a gas sulfur feed inlet and a quenching liquid feed inlet, and obtains the glassy elastomer after reaction in a reaction zone.

The specific temperature and state of the heated and gasified gas sulfur are not particularly limited in the present invention, and the temperature and state of the heated and gasified gas sulfur known to those skilled in the art can be selected and adjusted by those skilled in the art according to the actual production situation, raw material situation and product requirement.

The specific components and conditions of the quenching liquid are not particularly limited in principle, and may be selected and adjusted by those skilled in the art according to actual production conditions, raw material conditions and product requirements, and in order to better realize the quenching process and particle size control of the elastomer and ensure the quality such as thermal stability of the final product, the quenching liquid preferably comprises a mixed solution of solute sulfur and a solvent, or a mixed solution of solute sulfur, a solvent and insoluble sulfur, and more preferably a mixed solution of solute sulfur, a solvent and insoluble sulfur. The pressure of the quenching liquid is preferably 0.25-0.45 MPa, more preferably 0.28-0.43 MPa, more preferably 0.3-0.4 MPa, and more preferably 0.32-0.38 MPa. The temperature of the quenching liquid is preferably 40-60 ℃, more preferably 42-58 ℃, and more preferably 45-55 ℃. The mass ratio of the feeding amount of the quenching liquid to the feeding amount of the gaseous sulfur is preferably (110-250): 1, more preferably (130-220): 1, more preferably (150 to 200): 1, more preferably (170-180): 1.

the specific conditions of the reaction are not particularly limited in principle, and a person skilled in the art can select and adjust the reaction according to actual production conditions, raw material conditions and product requirements, in order to better realize the quenching process and particle size control of the elastomer and ensure the quality such as thermal stability of a final product, the temperature of the reaction, namely the temperature of a reaction zone, is preferably 80-100 ℃, more preferably 82-98 ℃, more preferably 85-95 ℃, and more preferably 87-93 ℃. The reaction time, i.e. the time of the glassy elastomer in the reaction zone, is preferably 0.5 to 1.5s, more preferably 0.7 to 1.3s, and more preferably 0.9 to 11 s.

The glassy state elastomer obtained by the invention falls into a liquid phase region under the action of gravity, and is subjected to medium-temperature curing after passing through a stirring paddle and a sieve plate, so as to obtain an insoluble sulfur semi-finished product. In the present invention, the above steps and the aforementioned reaction steps belong to a continuous production process, and are separately described for the sake of clarity.

The process of passing through the stirring paddle and the sieve plate is not particularly limited, and can be selected and adjusted by a person skilled in the art according to the actual production condition, the raw material condition and the product requirement. The temperature of the stirring paddle and the sieve plate, namely the temperature of the liquid phase zone, is preferably 55-80 ℃, more preferably 60-75 ℃, and more preferably 65-70 ℃.

In order to better realize uniform control of the particle size of the elastomer, prevent the elastomer from being oversize, ensure the quality of the final product such as thermal stability and the like, ensure the normal passing rate, prevent the elastomer from blocking sieve pores and meet the process requirement of continuous production, the process of passing through the stirring paddle and the sieve plate preferably also comprises a reverse flushing step of flushing a pipeline. The specific conditions of the back flushing are not particularly limited in the present invention, and can be selected and adjusted by those skilled in the art according to the actual production conditions, raw material conditions and product requirements, and the back flushing liquid is preferably a mixed liquid containing carbon disulfide, soluble sulfur and a small amount of insoluble sulfur. The reverse flushing pressure, namely the pressure of the spray head, is preferably 0.3-0.5 Mpa, more preferably 0.33-0.47 Mpa, more preferably 0.35-0.45 Mpa, and more preferably 0.37-0.42 Mpa.

In order to better improve the conversion rate and stability of insoluble sulfur and freeze the reaction in the shortest time to reduce the depolymerization of the insoluble sulfur, the step 1) of the invention is preferably as follows:

11) the method comprises the following steps of (1) passing a quenching liquid through a first feeding hole and passing heated and gasified gas sulfur through a second feeding hole through a quenching liquid feeding hole and a gas sulfur feeding hole, and feeding the gas sulfur into a venturi tube mixing reactor in the reactor for mixing to obtain a mixture;

12) and (3) spraying the mixture obtained in the step through a discharge hole of the Venturi tube mixing reactor in a reaction zone for reaction to obtain the glassy elastomer.

The specific parameter conditions for the mixing reaction in the venturi tube mixing reactor are not particularly limited in principle, and can be selected and adjusted by a person skilled in the art according to actual production conditions, raw material conditions and product requirements, the conversion rate and the stability of insoluble sulfur can be improved better, the freezing reaction can be carried out in the shortest time to reduce the depolymerization of the insoluble sulfur, and the outlet pressure of the quenching liquid feed port, namely the feed pressure of the first feed port, is preferably 0.3-0.6 Mpa, more preferably 0.35-0.55 Mpa, and more preferably 0.4-0.5 Mpa. The outlet pressure of the gas sulfur feed inlet, namely the feed pressure of the second feed inlet, is preferably 5-50 KPa, more preferably 15-40 KPa, and more preferably 25-30 KPa. In the present invention, the outlet end of the second feeding port is located in the negative pressure zone of the venturi tube mixing reactor, and the negative pressure in the negative pressure zone is preferably-0.01 to-0.06 MPa, more preferably-0.02 to-0.05 MPa, and more preferably-0.03 to-0.04 MPa. The negative pressure refers to gauge pressure of a vacuum gauge and is relative vacuum degree.

The invention then sprays the mixture obtained in the above steps through the discharge hole of the Venturi tube mixing reactor in the reaction zone for reaction to obtain the glass state elastomer. In the present invention, the above steps and the aforementioned reaction steps belong to a continuous production process, and are separately described for the sake of clarity.

The pressure of the injection is not particularly limited in the present invention, and can be selected and adjusted by those skilled in the art according to actual production conditions, raw material conditions and product requirements. The pressure of the injection is not particularly limited in the present invention, and can be selected and adjusted by those skilled in the art according to actual production conditions, raw material conditions and product requirements.

The specific conditions of the reaction are not particularly limited in principle, and a person skilled in the art can select and adjust the reaction according to actual production conditions, raw material conditions and product requirements, in order to better realize the quenching process and particle size control of the elastomer and ensure the quality such as thermal stability of a final product, the temperature of the reaction, namely the temperature of a reaction zone, is preferably 80-100 ℃, more preferably 82-98 ℃, more preferably 85-95 ℃, and more preferably 87-93 ℃. The reaction time, i.e. the time of the glassy elastomer in the reaction zone, is preferably 0.5 to 1.5s, more preferably 0.7 to 1.3s, and more preferably 0.9 to 1.1 s.

The glassy elastomer obtained by the invention falls into a liquid phase region under the action of gravity and is cured at medium temperature to obtain an insoluble sulfur semi-finished product. In the present invention, the above steps and the aforementioned reaction steps belong to a continuous production process, and are separately described for the sake of clarity.

In order to better realize the particle size control of the elastomer, better improve the thermal stability and the quality of a final product, ensure the normal passing rate and meet the process requirement of continuous production, the elastomer preferably also comprises a process of passing through a stirring paddle and a sieve plate after falling into a liquid phase region.

The process of passing through the stirring paddle and the sieve plate is not particularly limited, and can be selected and adjusted by a person skilled in the art according to the actual production condition, the raw material condition and the product requirement. The temperature of the stirring paddle and the sieve plate, namely the temperature of the liquid phase zone, is preferably 55-80 ℃, more preferably 60-75 ℃, and more preferably 65-70 ℃.

In order to better realize uniform control of the particle size of the elastomer, prevent the elastomer from being oversize, ensure the quality of the final product such as thermal stability and the like, ensure the normal passing rate, prevent the elastomer from blocking sieve pores and meet the process requirement of continuous production, the process of passing through the stirring paddle and the sieve plate preferably also comprises a reverse flushing step of flushing a pipeline. The specific conditions of the back flushing are not particularly limited in the present invention, and can be selected and adjusted by those skilled in the art according to the actual production conditions, raw material conditions and product requirements, and the back flushing liquid is preferably a mixed liquid containing carbon disulfide, soluble sulfur and a small amount of insoluble sulfur. The preferred pressure of the reverse flushing is 0.3-0.5 Mpa, more preferred is 0.33-0.47 Mpa, more preferred is 0.35-0.45 Mpa, more preferred is 0.37-0.42 Mpa.

The invention provides a production device of insoluble sulfur, which comprises an insoluble sulfur reactor and a three-stage series cyclone separator; and a solid-liquid mixed material discharge port of the reactor, which contains the insoluble sulfur semi-finished product and the quenching liquid, is connected with a feed port of a first-stage cyclone separator of the third-stage series cyclone separator. The invention improves the production device for producing insoluble sulfur, adds three-stage series cyclone separators, and utilizes the three-stage series cyclone separators to separate the solid-liquid mixed material containing the insoluble sulfur semi-finished product and the quenching liquid on density, thereby realizing the separation of high and low density quenching liquid, further achieving the purpose of reducing and stabilizing the density of the quenching liquid, and further improving the effect of the quenching process and the quality of the insoluble sulfur product. The production device provided by the invention realizes the recycling of the quenching liquid, greatly reduces the pollution or discharge of industrial waste liquid, is economic and environment-friendly, reduces the investment on raw materials, and greatly reduces the waste liquid amount in the production process.

The invention preferably adopts a vertical reactor, and realizes the continuous production process of insoluble sulfur; more set up stirring rake and sieve in the specific position of reactor, this important composite set for elastomer after the quenching filters through the sieve at the unloading in-process, and too big elastomer granule is by the sieve separation after, can also reduce the particle diameter through the shearing and the stirring effect of stirring rake, and then can reach the purpose that reduces the size of elastomer through the sieve. Meanwhile, the stirring paddle can adjust the stirring and shearing rotating speed at any time according to the characteristics of the materials, so that the comprehensive control of different working conditions is achieved. Furthermore, the invention improves the quenching equipment in the production device for producing the insoluble sulfur, and the venturi tube mixing reactor is arranged in the reactor, so that the forced mixing of the sulfur (gas and liquid) and the quenching liquid is realized by utilizing the characteristics of the venturi tube, and the effect of the quenching mixing reaction is greatly improved. The invention enters the Venturi tube mixing reactor in a synthesis reactor in a high-pressure mode, the quenching liquid is sprayed out in the Venturi tube mixing reactor in a high-speed atomizing nozzle mode, a negative pressure area is formed in a subsequent air suction chamber, sulfur (gas and liquid) enters the negative pressure area at certain pressure, is in high-intensity contact and mixing with the quenching liquid, enters the mixing chamber again, is in contact and mixing again, is cut by a cutter at certain pressure and then is sprayed into a reactor reaction area, the high-efficiency mixing of the quenching liquid and the sulfur (gas and liquid) and the rapid cooling of the sulfur (gas and liquid) are realized, the purpose of instantly reducing the temperature of gasified sulfur is achieved, the occurrence of depolymerization reaction of insoluble sulfur is effectively reduced, and the conversion rate and the thermal stability of a final product are greatly improved. The invention adopts special quenching equipment and quenching mode, thereby increasing quenching strength and quenching effect and improving the conversion rate and stability of insoluble sulfur. And the equipment and the process are simple, and the method is suitable for popularization and application of industrial mass production.

The production device and the production system provided by the invention realize the recycling of the quenching liquid, greatly reduce the pollution or discharge of industrial waste liquid, are economical and environment-friendly, reduce the investment on raw materials and greatly reduce the waste liquid amount in the production process.

Experimental results show that by adopting the production device and the production process of insoluble sulfur provided by the invention, after slurry is sequentially filtered by the sieve plate in the synthesis reactor, the particle size of solid particles in the slurry can be greatly reduced from about 200 mu m to 20-50 mu m, and the stability of insoluble sulfur of a product can be improved to a certain extent. And then through a dune tube mixing reactor, the forced mixing of the gas sulfur and the quenching liquid is realized, the effect of quenching mixing reaction is greatly improved, and the conversion rate and the thermal stability of the final product are improved. After separation by the hydrocyclone for three times, the quenching liquid can realize the control of quality and density, and is beneficial to the extreme cold effect. Meanwhile, the concentrated solution separated by the three hydrocyclones has high insoluble sulfur content (60-85 percent), thereby greatly reducing the load of subsequent separation, washing and drying.

In order to further illustrate the present invention, the following will describe the production apparatus and system of insoluble sulfur according to the present invention in detail with reference to the following examples, but it should be understood that these examples are implemented on the premise of the technical solution of the present invention, and the detailed embodiments and specific procedures are given only for further illustrating the features and advantages of the present invention, not for limiting the claims of the present invention, and the scope of the present invention is not limited to the following examples.

Example 1

(1) Melting and gasifying sulfur:

liquid sulfur (120-150 ℃) of 500kg/h is pumped to a heating furnace for heating, and after heat exchange with the flue gas of the heating furnace and radiation heating of a hearth, the sulfur is heated to 580 ℃ and enters a subsequent insoluble sulfur reactor.

(2) Quenching of sulphur

The sulfur gas (injected from the side part of the synthesis reactor) at 580 ℃ is contacted with the quenching liquid (injected from the top part of the synthesis reactor) generated in the subsequent process, the feeding flow rate of the quenching liquid is 75000kg/h, and the quenching liquid quenches the sulfur gas to ensure that the temperature of the sulfur gas is reduced to 70 ℃ in a very short time. The slurry is settled to the outlet of the synthesis reactor and is lifted to a three-stage series cyclone separator by a pump.

The slurry is lifted to a first-stage cyclone separator through a pump to carry out light and heavy component separation, the feeding amount of the first-stage cyclone separator is 80000kg/h (containing 4500kg/h of reflux), the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the first-stage cyclone separator enters a constant temperature tank to carry out low-temperature curing at 40-60 ℃, 77500kg/h of light component of the first-stage cyclone separator and 2500kg/h of reflux amount enter a second-stage cyclone separator, the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the second-stage cyclone separator, 77500kg/h of light component enters a third-stage cyclone separator, the pressure is 0.45Mpa, and 75000kg/h of the third-stage cyclone separator is used as recyclable quenching liquid to enter the top of a synthesis reactor.

Wherein the specific size of the first-stage to third-stage cyclone separators is shown in the attached drawing and is in unit mm.

(3) The slurry was subjected to subsequent aging in a constant temperature tank, centrifugal separation, washing and drying to obtain 267kg/h of insoluble sulfur powder with a yield of 53.4%.

The index detection of the insoluble sulfur prepared in the embodiment 1 of the invention is as follows:

heat stability at 120 deg.C for 15 min is 54.1%, average particle size is 28 μm, and purity is 95.8%.

Example 2

(1) Melting and gasifying sulfur

Liquid sulfur (120-150 ℃) of 500kg/h is pumped to a heating furnace for heating, and after heat exchange with the flue gas of the heating furnace and radiation heating of a hearth, the sulfur is heated to 580 ℃ and enters a subsequent synthesis reactor.

(2) Quenching of sulphur

The sulphur gas at 580 c (synthesis reactor side injection) is contacted with quench liquid from the subsequent process (synthesis reactor top injection) in a venturi inside the synthesis reactor.

Wherein, quench liquid is fed from the top feed inlet of the Venturi tube mixing reactor, the feed pressure of the quench liquid is 0.4Mpa, and the feed flow is 75000 kg/h.

Sulfur gas is fed from three side feeding ports of the Venturi tube mixing reactor simultaneously, the feeding pressure of the sulfur gas is 0.1Mpa, and the feeding flow is 500 kg/h. After entering the Venturi tube mixing reactor, the quenching liquid is sprayed into the negative pressure chamber through the nozzle to form a negative pressure area of the Venturi tube of-0.15 Mpa, and sulfur gas is further led to the mixing chamber. In the negative pressure zone, the quenching liquid is mixed with sulfur in high intensity, the quenching liquid quenches the sulfur gas, the temperature of the sulfur gas is reduced to 70 ℃ in a very short time, and the sulfur gas is mixed again by a mixing chamber at a certain pressure and sprayed into a reaction zone of a synthesis reactor by a cutter.

The temperature of the reaction zone is 80-100 ℃, and then the reaction zone enters a liquid phase zone, so that the temperature of the sulfur gas is reduced to 60-90 ℃ in a very short time. The slurry produced by the synthesis reactor is stirred by a stirrer and filtered by a sieve plate and is settled to the outlet of the synthesis reactor.

Wherein, three sets of stirring paddles, sieve plates and flushing pipelines are arranged in the synthesis reactor. The height of the liquid phase zone is 40% of the height of the vertical reactor, and the temperature of the liquid phase zone is 55-80 ℃; the first layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of an opening of the first layer of sieve plate is 5-20 mm, the distance between the stirring paddle and the sieve plate is 50-100 mm, a spray head with the diameter of 25mm is arranged on the flushing pipeline and used for spraying flushing liquid, and the distance between the spray head and the sieve plate is 20-60 cm; the second layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of the opening of the second layer of sieve plate is 60% -80% of the aperture of the opening of the first layer, the distance between the stirring paddle and the sieve plate is 50-100 mm, and a spray head with the diameter of 25mm is arranged on the flushing pipeline and used for spraying flushing liquid; the third layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of the opening of the third layer of sieve plate is 60% -80% of the aperture of the second layer of opening, and the distance between the stirring paddle and the sieve plate is 50-100 mm; the flushing pipeline is provided with a spray head for spraying flushing liquid.

(3) The slurry is settled to the outlet of the synthesis reactor and is lifted to a three-stage series cyclone separator by a pump.

The slurry is lifted to a first-stage cyclone separator through a pump to carry out light and heavy component separation, the feeding amount of the first-stage cyclone separator is 80000kg/h (containing 4500kg/h of reflux), the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the first-stage cyclone separator enters a constant temperature tank to carry out low-temperature curing at 40-60 ℃, 77500kg/h of light component of the first-stage cyclone separator and 2500kg/h of reflux amount enter a second-stage cyclone separator, the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the second-stage cyclone separator, 77500kg/h of light component enters a third-stage cyclone separator, the pressure is 0.45Mpa, and 75000kg/h of the third-stage cyclone separator is used as recyclable quenching liquid to enter the top of a synthesis reactor.

Wherein the specific size of the first-stage to third-stage cyclone separators is shown in the attached drawing and is in unit mm.

(4) After the slurry is cured in a subsequent constant-temperature tank and the materials are separated, the insoluble sulfur powder of 292.5kg/h is obtained after centrifugal separation, washing and drying, and the yield is 58.5%.

The index detection of the insoluble sulfur prepared in the embodiment 2 of the invention is as follows:

the thermal stability at 120 ℃ for 15 minutes was 55.9%. The average grain size is 25 μm, the conversion rate of sulfur is 58.5%, and the purity is 96.2%.

Example 3

(1) Melting and gasifying sulfur

Liquid sulfur (120-150 ℃) of 500kg/h is lifted to a heating furnace by a pump for heating, and after heat exchange with the flue gas of the heating furnace and radiation heating of a hearth, the sulfur is heated to 650 ℃ and enters a subsequent synthesis reactor.

(2) Quenching of sulphur

The 650 c sulphur gas (synthesis reactor side injection) is contacted with quench liquid (synthesis reactor top injection) from the subsequent process in a venturi inside the synthesis reactor.

Wherein, quench liquid is fed from the top feed inlet of the Venturi tube mixing reactor, the feed pressure of the quench liquid is 0.4Mpa, and the feed flow is 75000 kg/h.

Sulfur gas is fed from three side feeding ports of the Venturi tube mixing reactor simultaneously, the feeding pressure of the sulfur gas is 0.1Mpa, and the feeding flow is 500 kg/h. After entering the Venturi tube mixing reactor, the quenching liquid is sprayed into the negative pressure chamber through the nozzle to form a negative pressure area of the Venturi tube of-0.15 Mpa, and sulfur gas is further led to the mixing chamber. In the negative pressure zone, the quenching liquid is mixed with sulfur in high intensity, the quenching liquid quenches the sulfur gas, the temperature of the sulfur gas is reduced to 75 ℃ in a very short time, and the sulfur gas is mixed again by a mixing chamber at a certain pressure and sprayed into a reaction zone of a synthesis reactor by a cutter.

The temperature of the reaction zone is 80-100 ℃, and then the reaction zone enters a liquid phase zone, so that the temperature of the sulfur gas is reduced to 60-90 ℃ in a very short time. The slurry produced by the synthesis reactor is stirred by a stirrer and filtered by a sieve plate and is settled to the outlet of the synthesis reactor.

Wherein, three sets of stirring paddles, sieve plates and flushing pipelines are arranged in the synthesis reactor. The height of the liquid phase zone is 40% of the height of the vertical reactor, and the temperature of the liquid phase zone is 55-80 ℃; the first layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of an opening of the first layer of sieve plate is 5-20 mm, the distance between the stirring paddle and the sieve plate is 50-100 mm, a spray head with the diameter of 25mm is arranged on the flushing pipeline and used for spraying flushing liquid, and the distance between the spray head and the sieve plate is 20-60 cm; the second layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of the opening of the second layer of sieve plate is 60% -80% of the aperture of the opening of the first layer, the distance between the stirring paddle and the sieve plate is 50-100 mm, and a spray head with the diameter of 25mm is arranged on the flushing pipeline and used for spraying flushing liquid; the third layer of stirring paddle is a three-blade wing type paddle stirring paddle, the aperture of the opening of the third layer of sieve plate is 60% -80% of the aperture of the second layer of opening, and the distance between the stirring paddle and the sieve plate is 50-100 mm; the flushing pipeline is provided with a spray head for spraying flushing liquid.

(3) The slurry is settled to the outlet of the synthesis reactor and is lifted to a three-stage series cyclone separator by a pump.

The slurry is lifted to a first-stage cyclone separator through a pump to carry out light and heavy component separation, the feeding amount of the first-stage cyclone separator is 80000kg/h (containing 4500kg/h of reflux), the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the first-stage cyclone separator enters a constant temperature tank to carry out low-temperature curing at 40-60 ℃, 77500kg/h of light component of the first-stage cyclone separator and 2500kg/h of reflux amount enter a second-stage cyclone separator, the pressure is 0.45Mpa, 2500kg/h of heavy component at the outlet of the second-stage cyclone separator, 77500kg/h of light component enters a third-stage cyclone separator, the pressure is 0.45Mpa, and 75000kg/h of the third-stage cyclone separator is used as recyclable quenching liquid to enter the top of a synthesis reactor.

Wherein the specific size of the first-stage to third-stage cyclone separators is shown in the attached drawing and is in unit mm.

(4) After the slurry is cured in a subsequent constant-temperature tank and the materials are separated, the slurry is centrifugally separated, washed and dried to obtain 294.5kg/h of insoluble sulfur powder with the yield of 58.9 percent.

The index detection of the insoluble sulfur prepared in the embodiment 3 of the invention is as follows:

the thermal stability at 120 ℃ for 15 minutes was 56.3%. The average grain size is 24 μm, the conversion rate of sulfur is 58.9%, and the purity is 96.5%.

The above detailed description of a production apparatus and a production system for adjusting the density of a quench liquid in an insoluble sulfur production process according to the present invention is provided, and the principles and embodiments of the present invention are described herein using specific examples, which are provided only to help understand the method and its core ideas, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any apparatus or system, and implementing any combination of methods. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention. The scope of the invention is defined by the claims and may include other embodiments that occur to those skilled in the art. Such other embodiments are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

Claims (9)

1. The production device of the insoluble sulfur is characterized by comprising an insoluble sulfur reactor and a three-stage series cyclone separator;

a solid-liquid mixed material discharge port of the reactor, which contains the insoluble sulfur semi-finished product and the quenching liquid, is connected with a feed port of a first-stage cyclone separator of the third-stage series cyclone separator;

the upper part of the reactor is provided with a gas sulfur feeding hole and a quenching liquid feeding hole;

a Venturi tube mixer is arranged in the reactor;

the first feeding hole of the Venturi tube mixer is connected with the quenching liquid feeding hole;

the second feeding hole of the Venturi tube mixer is connected with the gas sulfur feeding hole;

the high-density mixed material discharge port of the primary cyclone separator is connected with the constant temperature tank;

in the three-stage series cyclone separator, a low-density liquid discharge port of the first-stage cyclone separator is connected with a feed port of the second-stage cyclone separator;

the low-density liquid discharge port of the second-stage cyclone separator is connected with the feed port of the third-stage cyclone separator;

the high-density liquid discharge port of the second-stage cyclone separator is connected with the feed port of the first-stage cyclone separator;

a low-density liquid discharge port of the third-stage cyclone separator is connected with a quenching liquid feed port of the insoluble sulfur reactor;

the high-density liquid discharge port of the third-stage cyclone separator is connected with the feed port of the second-stage cyclone separator;

the ratio of the diameter of the cylindrical section vortex cavity of the primary cyclone separator to the diameter of the cylindrical section vortex cavity of the secondary cyclone separator is (1.05-1.3): 1;

the ratio of the diameter of the bottom end of the conical section of the first-stage cyclone separator to the diameter of the bottom end of the conical section of the second-stage cyclone separator is (1.2-1.6): 1;

the ratio of the diameter of the cylindrical section vortex cavity of the secondary cyclone separator to the diameter of the cylindrical section vortex cavity of the tertiary cyclone separator is (1.1-1.4): 1;

the ratio of the diameter of the bottom end of the conical section of the second-stage cyclone separator to the diameter of the bottom end of the conical section of the third-stage cyclone separator is (1.4-1.6): 1.

2. the production plant according to claim 1, wherein the low-density liquid outlet of the three-stage cyclone, the quenching liquid inlet of the insoluble sulfur reactor and a fresh quenching liquid inlet source are connected;

the top end feed port of the Venturi tube mixer is a first feed port; the side feed inlet of the Venturi tube mixer is a second feed inlet;

a nozzle is arranged at one side of the top end feeding hole in the Venturi tube mixer;

the side feed inlet is positioned in a negative pressure area between the nozzle and the contraction section of the Venturi tube mixer;

the number of the side feeding openings is 2-6.

3. The production device according to claim 1, wherein one or more of a cutter, a screen, a perforated plate, a conical ball, a grating and a rotary fly-cutter are arranged at the throat of the venturi mixer;

the blade direction of the cutter faces the feeding direction;

the reactor is a vertical reactor;

the reactor is also internally provided with a stirring paddle and a sieve plate;

the stirring paddle is arranged below the reaction zone of the reactor and above the sieve plate;

the stirring paddle and the sieve plate are arranged in the liquid phase region;

a discharge hole is formed in the bottom of the reactor;

the aperture of the opening of the sieve plate is 5-20 mm.

4. The production device according to claim 3, wherein the stirring paddle comprises one or more of a two-blade oblique blade stirring paddle, a three-blade airfoil blade stirring paddle, a three-blade fan-shaped blade stirring paddle, a cambered blade stirring paddle, a curved-edge oblique blade stirring paddle, a composite folding blade stirring paddle and a three-blade rear tooth propeller stirring paddle;

the distance between the stirring paddle and the sieve plate is 50-100 mm;

the reactor comprises a reaction zone at the upper part in the reactor and a liquid phase zone at the lower part in the reactor;

a discharge hole at the bottom end of the Venturi tube mixer is arranged in the reaction zone;

a flushing pipeline is arranged in the reactor;

the flushing pipeline is positioned below the sieve plate; the liquid spraying direction of the flushing pipeline faces the sieve plate;

a stirring shaft is arranged in the center of the reactor along the vertical direction;

the stirring paddle is arranged on the stirring shaft.

5. The production device according to claim 4, wherein the number of the stirring paddles is n; the number of the sieve plates is n; the number of the flushing pipelines is n; n is 1-6;

when the number of the stirring paddles, the sieve plates and the flushing pipelines is multiple, the first stirring paddle is arranged above the first sieve plate, and the first flushing pipeline is arranged below the first sieve plate; a second stirring paddle is arranged above the second sieve plate, a second flushing pipeline is arranged below the second sieve plate, and the rest can be done in the same way;

the aperture of the opening of the single-layer sieve plate is 60-80% of the aperture of the opening of the upper-layer sieve plate;

the height of the liquid phase zone is 40% -50% of the height of the reactor;

the flushing pipelines are distributed in a net shape;

a spray head for spraying liquid is arranged on the flushing pipeline;

the distance between the spray head and the sieve plate is 20-60 cm;

the number of the spray heads is one or more;

the reactor further comprises a warming coil and/or a cooling coil;

the reactor comprises a conical bottom; the discharge hole is formed in the bottom end of the conical bottom.

6. An insoluble sulfur production system using the production apparatus according to any one of claims 1 to 5, comprising the steps of:

A) feeding the semi-finished product of the insoluble sulfur produced by the insoluble sulfur reactor into a first-stage cyclone separator of a third-stage series cyclone separator for first cyclone separation to obtain a first-stage low-density recovery quenching liquid and a high-density mixed material;

B) feeding the primary low-density recovered quenching liquid into a secondary cyclone separator for secondary cyclone separation to obtain secondary low-density recovered quenching liquid and secondary high-density liquid;

C) returning the secondary high-density liquid obtained in the step to a feed inlet of a primary cyclone separator for reflux and recirculation; meanwhile, feeding the secondary low-density recovered quenching liquid obtained in the step into a third-stage cyclone separator for third cyclone separation to obtain the quenching liquid capable of being recycled and a third-stage high-density liquid;

and returning the three-stage high-density liquid obtained in the step to a feed inlet of a second-stage cyclone separator for reflux and recycling.

7. The insoluble sulfur production system according to claim 6, wherein the temperature of the first cyclonic separation is 60-90 ℃;

the material feeding pressure of the primary cyclone separator is 0.3-0.6 Mpa;

the density of the primary low-density recovery quenching liquid is 1.4-1.5 kg/L; the density of the high-density mixed material is 1.8-1.9 kg/L;

the material feeding pressure of the secondary cyclone separator is 0.3-0.6 Mpa;

the density of the secondary low-density recovery quenching liquid is 1.3-1.4 kg/L; the density of the second-stage high-density liquid is 1.7-1.8 kg/L;

the material feeding pressure of the three-stage cyclone separator is 0.3-0.6 Mpa;

the density of the quenching liquid capable of being recycled is 1.2-1.3 kg/L; the density of the three-stage high-density liquid is 1.6-1.7 kg/L;

the insoluble sulfur reactor for producing the insoluble sulfur semi-finished product comprises the following specific steps:

1) feeding the heated and gasified gas sulfur and the quenching liquid into a production device of insoluble sulfur through a gas sulfur feed port and a quenching liquid feed port, and reacting in a reaction zone to obtain a glassy elastomer;

2) under the action of gravity, the elastomer falls into a liquid phase region, and is cured at medium temperature after passing through a stirring paddle and a sieve plate to obtain an insoluble sulfur semi-finished product.

8. The insoluble sulfur production system according to claim 7, wherein the temperature of the gaseous sulfur is 550 to 700 ℃;

the quenching liquid comprises a mixed solution of solute sulfur and a solvent, or a mixed solution of solute sulfur, a solvent and insoluble sulfur;

the pressure of the quenching liquid is 0.25-0.45 Mpa; the temperature of the quenching liquid is 40-60 ℃;

the mass ratio of the feeding amount of the quenching liquid to the feeding amount of the gas sulfur is (110-250): 1;

the step 1) is specifically as follows:

11) the method comprises the following steps of (1) passing a quenching liquid through a first feeding hole and passing heated and gasified gas sulfur through a second feeding hole through a quenching liquid feeding hole and a gas sulfur feeding hole, and feeding the gas sulfur into a venturi tube mixing reactor in the reactor for mixing to obtain a mixture;

12) the mixture obtained in the step is sprayed in a reaction zone through a discharge hole of a Venturi tube mixing reactor to react, so that a glassy elastomer is obtained;

the process of passing through the stirring paddle and the sieve plate also comprises a reverse flushing step of a flushing pipeline;

and the step A) also comprises the step of delivering the high-density mixed material into a constant-temperature tank for low-temperature curing to obtain insoluble sulfur.

9. The insoluble sulfur production system according to claim 8, wherein the negative pressure of the negative pressure zone at the outlet end of the second feed port is-0.01 to-0.06 MPa;

the outlet pressure of the quenching liquid feed inlet is 0.3-0.6 Mpa;

the outlet pressure of the gas sulfur feed inlet is 5-50 KPa;

the reaction temperature is 80-100 ℃;

the reaction time is 0.5-1.5 s;

the flushing fluid of the back flushing is a mixed solution containing carbon disulfide, soluble sulfur and a small amount of insoluble sulfur;

the pressure of the reverse flushing is 0.3-0.5 Mpa;

the temperature of the liquid phase region is 55-80 ℃;

the low-temperature curing temperature is 40-60 ℃.

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