阅读说明：本技术 用于生产不溶性硫磺的淬火器 (Quenching device for producing insoluble sulfur ) 是由 刘文奇 张夏青 马鲁齐 魏良 于 2018-06-29 设计创作，主要内容包括：本发明提供了一种用于生产不溶性硫磺的淬火器,其包括淬火器基座、淬火器压盖和淬火器出口扩大管,淬火器压盖固定连接在淬火器基座上；淬火器压盖上设置有多个锥体面,形成淬火液空腔,淬火器压盖的侧壁面上设置有一淬火液引入管,淬火液引入管与淬火液空腔连通,使得流体经过锥体面的间隙形成高压环状锥体液面；淬火器压盖上还设置有一淬火物料进料管,淬火器基座的中心部位设置有一膨胀腔,淬火液空腔和淬火物料进料管与膨胀腔连通；淬火器出口扩大管安装在淬火器基座的底端,与膨胀腔连通。本发明淬火后的收率明显增加,产品质量有了较大提升,成粉效果较好,减少了后续处理工艺,降低了生产成本和安全风险。(The invention provides a quenching device for producing insoluble sulfur, which comprises a quenching device base, a quenching device gland and a quenching device outlet expanding pipe, wherein the quenching device gland is fixedly connected to the quenching device base; the quenching device comprises a quenching device gland, a quenching liquid inlet pipe, a quenching liquid outlet pipe and a quenching liquid inlet pipe, wherein the quenching device gland is provided with a plurality of conical surfaces to form a quenching liquid cavity; the quenching device pressure cover is also provided with a quenching material feeding pipe, the central part of the quenching device base is provided with an expansion cavity, and the quenching liquid cavity and the quenching material feeding pipe are communicated with the expansion cavity; the quenching device outlet expansion pipe is arranged at the bottom end of the quenching device base and is communicated with the expansion cavity. The method obviously increases the yield after quenching, greatly improves the product quality, has good powdering effect, reduces subsequent treatment processes, and reduces the production cost and the safety risk.)

1. The quenching device for producing insoluble sulfur is characterized by comprising a quenching device base, a quenching device gland and a quenching device outlet expanding pipe, wherein the quenching device gland is fixedly connected to the quenching device base;

the quenching device comprises a quenching device gland, a quenching liquid inlet pipe, a quenching liquid outlet pipe and a quenching liquid inlet pipe, wherein the quenching device gland is provided with a plurality of conical surfaces to form a quenching liquid cavity;

the quenching device comprises a quenching device base, a quenching liquid cavity, a quenching material feeding pipe and a quenching liquid cavity, wherein the quenching device base is arranged on the quenching device pressure cover;

the quenching device outlet expansion pipe is arranged at the bottom end of the quenching device base and communicated with the expansion cavity.

2. The quench for producing insoluble sulfur according to claim 1, wherein two conical surfaces are provided on the quench gland.

3. The quench for producing insoluble sulfur according to claim 1, wherein a seal gasket is disposed between the quench gland and the quench base.

4. The quench for producing insoluble sulfur according to claim 3, wherein the clearance between the quench base and the conical surface of the quench gland is adjusted by adjusting the thickness of the seal face gasket.

5. The quench apparatus for producing insoluble sulfur according to claim 4, wherein said sealing gasket has a thickness of 0.5 mm to 5mm and a pressure of 0.5MPa to 1.3MPa in said expansion chamber.

6. The quench apparatus of claim 1 for producing insoluble sulfur wherein the expansion chamber is injected into the quenching apparatus from the quench outlet enlarged tube at an angle of from 5 ° to 30 °.

7. The quench for producing insoluble sulfur according to claim 1, wherein the quench base is bolted to the quench gland by bolts and nuts.

8. The quench apparatus for producing insoluble sulfur according to claim 1 wherein said expansion chamber is tapered from top to bottom.

9. The quench for producing insoluble sulfur according to claim 8, wherein the lower converging portion of the expansion chamber is provided with an equipment connection flange for connection with quenching equipment, and the lower converging portion of the expansion chamber is connected with the quench outlet expansion pipe.

10. The quench for producing insoluble sulfur according to claim 1, wherein the end of the quench liquid introduction pipe is provided with a feed flange.

11. The quench for producing insoluble sulfur according to any one of claims 1 to 10, wherein the angle of the conical surface is from 45 ° to 75 °.

Technical Field

The invention relates to the field of quenchers, in particular to a quencher for producing insoluble sulfur.

Background

In the prior art, insoluble sulfur is elastic sulfur with a transparent and amorphous chain structure, which is obtained by heating sulfur powder to boiling (444.6 ℃) and quenching the sulfur powder in cold water. Or diluting the superheated sulfur vapor with inert gas, spraying into cold water fog, cooling to below 90 deg.C, or dissolving sulfur block in ammonia, and spray drying.

Generally, processes for producing insoluble sulfur are largely classified into vapor phase processes and liquid phase processes. Most of the insoluble sulfur is produced by adopting a vapor phase method, the production process for producing the insoluble sulfur by adopting the vapor phase method is mature, but the vapor phase method has the defects of large equipment investment, high energy consumption, flammability, explosiveness and the like, and the development of the production of the insoluble sulfur is restricted. In addition, the adopted liquid phase method process is basically pouring or dripping, the produced insoluble crude sulfur is blocky, and the conversion rate is low due to insufficient polymerization and cooling.

In the existing quenching device for producing insoluble sulfur, quenching materials are directly sprayed into quenching liquid or are simply mixed and are sprayed into quenching equipment in a blocky manner, and mechanical crushing is carried out after filtering and drying, so that the crushing process is added, the investment cost and the production cost are improved, and dust explosion easily occurs due to mechanical crushing into powder.

In view of the above, there is a need in the art to develop a new quench that is more efficient and safer.

Disclosure of Invention

The invention aims to overcome the defects that the quenching device in the prior art is high in cost and easy to cause dust explosion, and provides a quenching device for producing insoluble sulfur.

The invention solves the technical problems through the following technical scheme:

the quenching device for producing insoluble sulfur is characterized by comprising a quenching device base, a quenching device gland and a quenching device outlet expanding pipe, wherein the quenching device gland is fixedly connected to the quenching device base;

the quenching device comprises a quenching device gland, a quenching liquid inlet pipe, a quenching liquid outlet pipe and a quenching liquid inlet pipe, wherein the quenching device gland is provided with a plurality of conical surfaces to form a quenching liquid cavity;

the quenching device comprises a quenching device base, a quenching liquid cavity, a quenching material feeding pipe and a quenching liquid cavity, wherein the quenching device base is arranged on the quenching device pressure cover;

the quenching device outlet expansion pipe is arranged at the bottom end of the quenching device base and communicated with the expansion cavity.

According to one embodiment of the invention, two conical surfaces are provided on the quench gland.

According to one embodiment of the invention, a seal face gasket is disposed between the quench gland and the quench base.

According to one embodiment of the invention, the clearance between the quench base and the conical face of the quench gland is adjusted by adjusting the thickness of the seal face gasket.

According to one embodiment of the invention, the thickness of said sealing gasket is between 0.5 and 5mm and the pressure inside said expansion chamber is between 0.5 and 1.3 MPa.

According to one embodiment of the invention, the expansion chamber is injected into the quench apparatus at an angle from the quench outlet enlarged tube, the angle being 5-30 °.

According to one embodiment of the invention, the quench base and the quench gland are connected by bolts and nuts.

According to one embodiment of the invention, the expansion chamber is tapered from top to bottom.

According to one embodiment of the invention, an equipment connecting flange is arranged at the lower end closing-in of the expansion cavity and used for being connected with quenching equipment, and the lower end closing-in of the expansion cavity is connected with the quenching device outlet expansion pipe.

According to one embodiment of the invention, the end of the quench liquid inlet pipe is provided with a feed flange.

According to one embodiment of the invention the angle of the cone face is 45-75 °.

The positive progress effects of the invention are as follows:

the quenching device for producing insoluble sulfur of the invention forms a granular or powdery material by spraying and quenching gas-phase materials and liquid-phase materials together. Because the contact specific surface area of the two substances is increased, the yield after quenching is obviously increased, the product quality is greatly improved, the powdering effect is better, the subsequent treatment process is reduced, and the production cost and the safety risk are reduced.

Drawings

The above and other features, properties and advantages of the present invention will become more apparent from the following description of the embodiments with reference to the accompanying drawings in which like reference numerals denote like features throughout the several views, wherein:

FIG. 1 is a schematic diagram of the structure of a quenching device for producing insoluble sulfur according to the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

Further, although the terms used in the present invention are selected from publicly known and used terms, some of the terms mentioned in the description of the present invention may be selected by the applicant at his or her discretion, the detailed meanings of which are described in relevant parts of the description herein.

Furthermore, it is required that the present invention is understood, not simply by the actual terms used but by the meaning of each term lying within.

FIG. 1 is a schematic diagram of the structure of a quenching device for producing insoluble sulfur according to the present invention.

As shown in FIG. 1, the invention discloses a quenching device for producing insoluble sulfur, which comprises a quenching device base 10, a quenching device gland 20 and a quenching device outlet expanding pipe 30, wherein the quenching device gland 20 is fixedly connected on the quenching device base 10. Preferably, the quench base 10 and the quench gland 20 are connected by bolts 40 and nuts 50.

The quench gland 20 is provided with a plurality of conical surfaces 21 to form a quench liquid cavity a, and in this embodiment, the quench gland 20 is provided with two conical surfaces 21 (as shown in fig. 1). Of course, the two conical surfaces 21 are only examples, and the number of the conical surfaces 21 is not limited in practice and is determined according to actual working conditions. In addition, the structure on the quenching press cover 20 is not limited to providing the conical surface 21, and this is only an example, and the conical surface 21 may be replaced by a structure with another shape, which is determined according to the actual working condition. A quenching liquid introducing pipe 22 is arranged on the side wall surface of the quenching device gland 20, and the quenching liquid introducing pipe 22 is communicated with the quenching liquid cavity a, so that fluid passes through the gap of the cone surface 21 to form a high-pressure annular cone liquid surface. A feed flange 23 is provided at the end of the quench liquid introduction pipe 22. The angle of the cone face 21 is preferably 45-75 deg., preferably larger and smaller. The quenching liquid introduction pipe 22 is inclined at the same angle as the quenching apparatus outlet enlarged pipe 30.

The quenching press cover 20 is also provided with a quenching material feeding pipe 24, the central part of the quenching device base 10 is provided with an expansion cavity 11, and the quenching liquid cavity a and the quenching material feeding pipe 24 are communicated with the expansion cavity 11. The quencher outlet-enlarging tube 30 is installed at the bottom end of the quencher base 10, communicating with the expansion chamber 11.

Preferably, a seal face gasket 60 is disposed between the quench gland 20 and the quench base 10. The thickness of the sealing gasket is 0.5-5 mm. The clearance between the quench base 10 and the conical surface 21 of the quench gland 20 is adjusted by adjusting the thickness of the seal face gasket 60 between the quench base 10 and the quench gland 20. The jet speed of the quenching liquid can be controlled by adjusting the size of the gap, so that the shearing and contact effects of the two substances are controlled.

Meanwhile, the pressure of the expansion cavity is controlled, so that the quenching effect and the particle size of the solid material are influenced. The smaller the expansion pressure, the larger the particles formed, but there is a limit that is so small that they are liable to cause clogging of the nozzle, not only of the type in which they are formed. The pressure in the expansion chamber is preferably in the range of 0.5-1.3 MPa. The pressure is lower than 0.5MPa, the shearing force cannot be reached, and particles cannot be formed, so that the nozzle is blocked. The pressure is higher than 1.3MPa, the annular gap is too small, the processing difficulty is larger, and the annular gap is easily blocked by foreign matters to cause bias flow. The larger the gap, the smaller the pressure, the smaller the flow velocity, and the smaller the shear force. The smaller the pressure, the larger the particles formed.

Further preferably, the expansion chamber 11 is tapered from top to bottom. An equipment connecting flange 12 is arranged at the lower end closing-in part of the expansion cavity 11 and used for being connected with quenching equipment, and the lower end closing-in part of the expansion cavity 11 is connected with the quenching device outlet expanded pipe 30.

According to the structural description, the quenching device for producing insoluble sulfur mainly depends on the fluid from the quenching liquid inlet pipe 22 to form a high-pressure annular cone liquid level through the gap of the cone surface, and the high-pressure annular cone liquid level is in continuous contact with the gas-phase fluid from the quenching material feeding pipe 24 to form uniform solid-liquid mixed material to be sprayed into the expansion cavity. A liquid seal is formed at the mouth of the expansion chamber 11 and is ultimately injected into the quenching apparatus at an angle from the quench outlet enlarged tube 30 by virtue of the pressure within the chamber. The angle is preferably 5-30 degrees, and the design aims to ensure the slow expansion process of the materials from the high-pressure area to the low-pressure area, ensure the spraying effect, better pulverize and control the particle size of the pulverized materials. Meanwhile, the material is sprayed into the quenching equipment at a certain angle, so that the phenomenon that the material is adhered to the inner wall of the equipment due to splashing of the material is avoided.

More specifically, the quenching liquid is conveyed to the quencher by an external conveying device, and enters the quencher through the quenching liquid introduction pipe 22. And an annular cone liquid level is formed in a gap between the quenching device base 10 and the cone surface of the quenching device upper gland 20 and sprayed into the expansion cavity 11, and the annular cone liquid level is fully mixed and quenched with the gas-phase material from the quenching material feeding pipe 24 to form a solid-liquid mixed material.

Then, a certain liquid seal is formed at the closing-in of the expansion cavity 11, and finally the liquid seal is sprayed into quenching equipment through the quenching device outlet expanding pipe 30 under a certain pressure to complete the whole quenching process, and finally granular materials are formed.

In addition, the change of the scheme can be realized by adjusting the gap between the quenching device base and the conical surface of the quenching device gland, and the whole structure does not change greatly. The length of the bell mouth at the lower part is related to the diameter of the tank body and the control height of the liquid level, the distance between the outlet of the expansion pipe and the liquid level is controlled to be at least more than 50cm, and the materials are further expanded and dispersed after coming out. If the temperature is too low, the liquid level material is easy to splash to the expansion pipe to form up-down backflushing. Meanwhile, the liquid level is not suitable to be too low, and the sprayed materials completely enter the liquid level below and do not directly contact the inner wall of the equipment according to the spraying expansion condition of the materials. The height adjustment may shorten the enlarged tube length by continuous physical cutting.

In conclusion, the quenching device for producing the insoluble sulfur is used for quenching the gas-phase material and the liquid-phase material together by spraying, so as to form a granular or powdery material. Because the contact specific surface area of the two substances is increased, the yield after quenching is obviously increased, the product quality is greatly improved, the powdering effect is better, the subsequent treatment process is reduced, and the production cost and the safety risk are reduced.

The method is mainly applied to producing insoluble sulfur, and can also be used for processes of rapidly cooling, quenching, milling and the like after gasifying other products, such as milling of some low-boiling-point metals and the like.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that these are by way of example only, and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the invention, and these changes and modifications are within the scope of the invention.