CN214233964U - Cracking cylinder, cracking equipment and cracking system - Google Patents

Abstract

The application discloses a cracking tube, schizolysis equipment and schizolysis system, wherein, cracking tube includes: the feeding straight cylinder section is cylindrical; the spiral barrel section is spiral, one end of the spiral barrel section is fixedly communicated with the feeding straight barrel section, a spiral material channel is formed in the spiral barrel section, and a spiral space is formed outside the spiral barrel section; the discharging straight cylinder section is cylindrical, and the other end of the spiral cylinder section is fixedly communicated with the discharging straight cylinder section; the supporting sleeve is sleeved outside the spiral cylinder section, the cylinder wall of the supporting sleeve is provided with a plurality of air holes, and the air holes are communicated with the spiral space. The spiral space that this spiral section of thick bamboo of schizolysis outside formed can with the inside intercommunication of cartridge heater, consequently, the heating gas in the cartridge heater passes through the air vent on the support sleeve and transfers heat to the spiral section of thick bamboo in getting into the spiral space, and the heat transfer area of the spiral section of thick bamboo in this application increases greatly to improve heat transfer efficiency and heat utilization rate, more be favorable to going on of schizolysis reaction.

Description

Cracking cylinder, cracking equipment and cracking system

Technical Field

The utility model relates to a chemical industry equipment technical field, in particular to a cracking barrel, the utility model discloses still relate to a cracking equipment and schizolysis system that contain this cracking barrel.

Background

Cracking equipment is common production equipment in the chemical field. The existing cracking equipment mainly comprises a cracking cylinder and a heating cylinder, wherein the heating cylinder is sleeved on the periphery of the cracking cylinder, the heating cylinder which is fixedly arranged relative to the cracking cylinder is in rotary motion, materials move in the cracking cylinder in a rolling manner, and heat generated by the heating cylinder is transferred to the materials in the cracking cylinder through the cylinder wall of the cracking cylinder. However, the heat transfer efficiency of the cracking equipment is low, and the cracking equipment is not beneficial to cracking organic matters.

In summary, how to improve the heat transfer efficiency of the cracking equipment becomes a problem to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention provides a cracking cylinder to improve heat transfer efficiency.

Another object of the present invention is to provide a cracking apparatus comprising the cracking cylinder, so as to improve the heat transfer efficiency.

It is still another object of the present invention to provide a cracking system comprising the cracking apparatus, so as to improve the heat transfer efficiency.

In order to achieve the above purpose, the utility model provides the following technical scheme:

a lysis cartridge comprising:

the feeding straight cylinder section is cylindrical;

the spiral barrel section is spiral, one end of the spiral barrel section is fixedly communicated with the feeding straight barrel section, a spiral material channel is formed in the spiral barrel section, and a spiral space is formed outside the spiral barrel section;

the discharging straight cylinder section is cylindrical, and the other end of the spiral cylinder section is fixedly communicated with the discharging straight cylinder section;

the supporting sleeve is sleeved outside the spiral cylinder section, the cylinder wall of the supporting sleeve is provided with a plurality of air holes, and the air holes are communicated with the spiral space.

Preferably, in the above described cracking cylinder, the ventilation holes are arranged spirally along the axial direction of the support sleeve.

Preferably, in the above-mentioned cracking cylinder, the spiral direction of the vent holes is the same as or opposite to the spiral direction of the spiral cylinder section.

Preferably, in the above cracking cylinder, the vent holes are surrounded by a perforated plate, and the perforated plate is fixed to the outer wall surface of the support sleeve through an annular base.

Preferably, in the cracking cylinder, a reinforcing ring plate is further arranged at the connecting position of the orifice plate and the annular base.

Preferably, in the cracking cylinder, the supporting sleeve is fixedly connected with the feeding straight cylinder section and/or the discharging straight cylinder section.

Preferably, in the cracking cylinder, the spiral cylinder section is an annular spiral cylinder section, and the central axis of the annular spiral cylinder section is a hollow structure.

The application also provides a cracking device, including a cracking barrel and a heating cylinder, the cracking barrel be as above arbitrary the cracking barrel, the both ends of heating cylinder are sealed cover respectively and are located the straight section of thick bamboo section of feeding of cracking barrel with the periphery of the straight section of thick bamboo section of ejection of compact, the spiral section of thick bamboo section of cracking barrel is located in the heating cylinder, the inside of heating cylinder with the spiral space of spiral section of thick bamboo section communicates with each other, the setting of cracking barrel relatively fixed the rotary motion is done to the heating cylinder.

Preferably, in the cracking apparatus, the heating cylinder is a combustion cylinder for combusting energy to generate hot gas;

or an electric heating device is arranged in the heating cylinder and used for heating the gas in the heating cylinder;

or the heating cylinder is communicated with an external hot gas source and is used for introducing hot gas into the heating cylinder.

The application also provides a cracking system, including drying equipment and cracking equipment, the cracking equipment be as above the cracking equipment, drying equipment's material export with the feed arrangement intercommunication of cracking equipment.

Preferably, in the cracking system, a gas inlet and outlet of a heating cylinder of the cracking device is communicated with the drying device.

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

the utility model provides a cracking cylinder which comprises a feeding straight cylinder section, a spiral cylinder section, a discharging straight cylinder section and a supporting sleeve, wherein, two ends of the spiral cylinder section are respectively fixedly communicated with the feeding straight cylinder section and the discharging straight cylinder section, the spiral cylinder section is spiral, a spiral material channel is formed in the spiral cylinder section, and a spiral space is formed outside the spiral cylinder section; the supporting sleeve is sleeved outside the spiral cylinder section, the cylinder wall of the supporting sleeve is provided with a plurality of air holes, and the air holes are communicated with the spiral space. The cracking cylinder is applied to cracking equipment, the two ends of the heating cylinder are hermetically sleeved on the peripheries of the feeding straight cylinder section and the discharging straight cylinder section of the cracking cylinder, and the spiral cylinder section and the supporting sleeve are located in the heating cylinder. The schizolysis section of thick bamboo is rotatory, the material gets into the spiral section of thick bamboo section through the straight section of thick bamboo of feeding, and remove to the straight section of thick bamboo section of ejection of compact gradually along with the rotation of spiral section of thick bamboo section in the spiral material passageway in the spiral section of thick bamboo, because the inside outside spiral space intercommunication with the spiral section of thick bamboo of heating, therefore, the heating gas in the heating cylinder transfers heat to the spiral section of thick bamboo in getting into the spiral space through the air vent on the supporting sleeve, compare in the schizolysis section of thick bamboo of current straight tube-shape, the heat transfer area of the spiral section of thick bamboo in this application increases greatly, thereby heat transfer efficiency and heat utilization rate have been improved, more be favorable to going on of schizolysis reaction, and support the spiral section of thick bamboo through the supporting sleeve, prevent spiral section of thick bamboo bending deformation, improve its structural strength.

The utility model provides a cracking equipment has adopted the schizolysis section of thick bamboo in this application, consequently, has increased the heat transfer area of the heating gas in the cartridge heater and schizolysis section of thick bamboo to improve heat transfer efficiency and heat utilization rate, be favorable to the schizolysis reaction.

The utility model provides a cracking system includes drying equipment and cracking equipment, and cracking equipment adopts the cracking equipment in this application, has consequently improved heat transfer efficiency and heat utilization rate, is favorable to the schizolysis reaction.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a cracking cylinder according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a spiral tube section of a cracking tube according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a supporting sleeve of a cracking cylinder according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of an air vent of a support sleeve of a cracking apparatus according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a cracking apparatus provided in an embodiment of the present invention;

fig. 6 is a schematic side view of a heating cylinder of a cracking apparatus according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a cracking system according to an embodiment of the present invention.

Wherein, 1 is a feeding device, 2 is a cracking cylinder, 21 is a feeding straight cylinder section, 22 is a spiral cylinder section, 221 is a spiral space, 23 is a discharging straight cylinder section, 24 is a supporting sleeve, 241 is a vent hole, 242 is a pore plate, 243 is a reinforcing ring plate, 244 is an annular base, 3 is a driving device, 4 is a heating cylinder, 41 is a gas inlet and outlet, 42 is an observation port, 43 is an ignition port, 44 is a waste outlet, 5 is a sealing ring, 6 is a cracking gas outlet port, 7 is a discharging device, 8 is a discharging device, and 9 is drying equipment.

Detailed Description

The core of the utility model is to provide a cracking cylinder, which improves the heat transfer efficiency.

The utility model also provides a pyrolysis apparatus who contains this pyrolysis section of thick bamboo has improved heat transfer efficiency.

The utility model also provides a schizolysis system that contains this schizolysis equipment has improved heat transfer efficiency.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, an embodiment of the present invention provides a cracking cylinder 2, which includes a feeding straight cylinder section 21, a spiral cylinder section 22, a discharging straight cylinder section 23, and a supporting sleeve 24; wherein, the feeding straight cylinder section 21 is cylindrical, and one end of the feeding straight cylinder section 21 is a feeding end; the discharging straight cylinder section 23 is cylindrical, and one end of the discharging straight cylinder section 23 is a discharging end; the spiral cylinder section 22 is spiral, two ends of the spiral cylinder section 22 are respectively fixedly communicated with the feeding straight cylinder section 21 and the discharging straight cylinder section 23, a spiral material channel is formed in the spiral cylinder section 22 and used for materials to pass through, and a spiral space 221 is formed outside the spiral cylinder section 22 and used for being communicated with heating gas; the supporting sleeve 24 is sleeved outside the spiral cylinder section 22, the cylinder wall of the supporting sleeve 24 is provided with a plurality of vent holes 241, and the vent holes 241 are communicated with the spiral space 221.

The cracking cylinder 2 is applied to a cracking device, the two ends of the heating cylinder 4 are hermetically sleeved on the peripheries of the feeding straight cylinder section 21 and the discharging straight cylinder section 23 of the cracking cylinder 2, and the spiral cylinder section 22 and the supporting sleeve 24 are positioned in the heating cylinder 4. The heating cylinder 4 that the relatively fixed of pyrolysis cylinder 2 set up is rotatory, the material gets into spiral cylinder section 22 through feeding straight section of thick bamboo section 21, and move to ejection of compact straight section of thick bamboo section 23 along with spiral cylinder section 22's rotation gradually in the spiral material passageway in spiral cylinder section 22, because the inside spiral space 221 with the outside of spiral cylinder section 22 of heating cylinder 4 communicates, consequently, the heating gas in the heating cylinder 4 gets into spiral space 221 through the air vent 241 on the supporting sleeve 24 and transfers heat to spiral cylinder section 22 in, the heat passes to the material in the spiral material passageway again, heat the material. Compare in the pyrolysis cylinder of current straight tube-shape, pyrolysis cylinder 2 has increased heat transfer area greatly through the helical structure of spiral cylinder section of thick bamboo section 22 in this application to improve heat transfer efficiency and heat utilization rate, more be favorable to going on of pyrolysis reaction. Meanwhile, the spiral cylinder section 22 is reinforced and supported by the supporting sleeve 24, so that the spiral cylinder section 22 is prevented from bending and deforming, and the heating cylinder 4 is communicated with the spiral space 221 through the vent holes 241 formed in the supporting sleeve 24, so that the heating gas in the heating cylinder 4 can enter the spiral space 221 to transfer heat to the cracking cylinder 2. And the vent 241 reduces or prevents the solid or liquid material in the heating cylinder 4 from entering the spiral space 221 through the vent 241 as much as possible, because the heating cylinder 4 is fixedly arranged, the solid or liquid material usually stays at the bottom of the heating cylinder 4 and is not easy to enter the vent, and the heating gas in the heating cylinder 4 can diffuse and convect to enter the spiral space 221 through the vent 241, thereby further ensuring that the heating gas better flows through in the spiral space 221 for heat transfer.

Further, in the present embodiment, the ventilation holes 241 are spirally arranged along the axial direction of the support sleeve 24, and the plurality of ventilation holes 241 are uniformly distributed, so as to further improve the uniformity of the gas heat transfer.

Further, in the present embodiment, the spiral direction of the ventilation hole 241 is the same as or opposite to the spiral direction of the spiral cylindrical section 22. Preferably, the spiral direction of the ventilation holes 241 is the same as the spiral direction of the spiral cylinder section 22, and the ventilation holes 241 are arranged corresponding to the spiral space 221, so that the heating gas can enter the spiral space 221 quickly.

Of course, the shape, size and number of the vent holes 241 are not limited in this embodiment, the vent holes 241 may be any shape, such as circular, rectangular, oval, quincunx, etc., as long as it is beneficial for the gas to pass through, the size of the vent holes 241 depends on the heating requirement, if the heating requirement is large, the larger vent holes 241 may be provided to ensure sufficient circulation of the heating gas, and conversely, the smaller vent holes 241 may be provided. The number of the vent holes 241 is also set according to the heating requirement, and the more the vent holes 241 are, the smoother the circulation of the heating gas in the spiral space 221 is, the faster the heating speed is, otherwise, the slower the heating speed is, but at the same time, it is ensured that the solid and liquid materials in the heating cylinder 4 are prevented from entering the spiral space 221 as much as possible.

As shown in fig. 4, in the present embodiment, the vent holes 241 are defined by the orifice plate 242, the orifice plate 242 is fixed to the outer wall surface of the support sleeve 24 through the annular base 244, and the orifice plate 242 protrudes from the outside of the support sleeve 24, so that the inlets of the vent holes 241 are higher than the outer surface of the support sleeve 24, which can effectively prevent solid and liquid materials in the heater cartridge 4 from entering the vent holes 241.

Further, in the present embodiment, a reinforcing ring plate 243 is further disposed at the connecting position of the orifice plate 242 and the annular base 244, and the structural strength of the vent 241 is improved by the reinforcing ring plate 243, so that the vent is not easily deformed by heat.

In the present exemplary embodiment, the support sleeve 24 is fixedly connected to the feed straight section 21 and/or the discharge straight section 23. That is, the supporting sleeve 24 may have one end fixedly connected to the feeding straight cylinder section 21, one end fixedly connected to the discharging straight cylinder section 23, and two ends fixedly connected to the feeding straight cylinder section 21 and the discharging straight cylinder section 23, respectively. Thereby the supporting cylinder section 24 and the feeding straight cylinder section 21, the spiral cylinder section 22 and the discharging straight cylinder section 23 are rotated together as a whole, and the friction between the supporting cylinder section 24 and the spiral cylinder section 22 is reduced. Preferably, only one end of the supporting cylinder section 24 is fixedly connected with the feeding straight cylinder section 21 or the discharging straight cylinder section 23, so that the stress of the fixed connection position of the supporting cylinder section 24 caused by the heated axial deformation of the spiral cylinder section 22 can be reduced, and the service life is prolonged.

Of course, the supporting cylinder section 24 may also be directly connected to the stationary heating cylinder 4 instead of being fixedly connected to the feeding straight cylinder section 21 and the discharging straight cylinder section 23, so that the spiral cylinder section 22 rotates relative to the supporting cylinder section 24 without affecting the passage and heat transfer of the heating gas.

In this embodiment, the screw cylinder section 22 is the annular screw cylinder section, and the central axis department of annular screw cylinder section is hollow structure, has radial interval between the inner circle of annular screw cylinder section and the axis of a pyrolysis tube 2, so sets up, can alleviate the weight of screw cylinder section 22, and the material mainly removes in the bottom of spiral material passageway, consequently, the demand that the material removed can be satisfied to the annular screw cylinder section.

Of course, the helical cylinder section 22 may not be provided with a hollow structure, and material conveying and heating can be realized as well.

Preferably, in this embodiment, the difference between the outer ring diameter and the inner ring diameter of the annular spiral cylinder section is greater than 5cm, and the difference between the outer ring diameter and the inner ring diameter of the annular spiral cylinder section is determined according to the material quantity.

Preferably, in the present embodiment, the width of the spiral space 221 formed outside the spiral cylindrical section 22 is 1cm to 100cm, and the width determines the heating amount and the heat dissipation area, and ensures the convection and turbulence of the hot air flow. More preferably, the width of the spiral space 221 is about 50 cm.

In the present embodiment, the pitch of the helical cylindrical section 22 is a constant pitch or a variable pitch, and the pitch is greater than 1 cm. And determining the form and the size of the screw pitch according to the temperature gradient and the carbonization requirement of different axial sections in the cracking cylinder 2.

As shown in fig. 5, based on the described cracking tube 2 of any of the above embodiments, the embodiment of the present invention further provides a cracking apparatus, including the cracking tube 2 and the heating tube 4, wherein, the cracking tube 2 is the cracking tube 2 described in any of the above embodiments, the two ends of the heating tube 4 are respectively sealed and sleeved on the peripheries of the feeding straight tube section 21 and the discharging straight tube section 23 of the cracking tube 2, the spiral tube section 22 of the cracking tube 2 is located in the heating tube 4, the inside of the heating tube 4 is communicated with the spiral space 221 of the spiral tube section 22, and the heating tube 4 which is relatively fixed and arranged on the cracking tube 2 is rotated.

This cracking equipment during operation, the material passes through in the feed end entering spiral cylinder section 22 of the straight section of thick bamboo 21 of feeding, along with the rotation of cracking cylinder 2, the material is automatic to the straight section of thick bamboo 23 removal of ejection of compact in the spiral material passageway in spiral cylinder section 22, and this in-process, the heating gas in the cartridge heater 4 flows in the outside spiral space 221 of spiral cylinder section of thick bamboo 22, and the heating gas heats spiral cylinder section of thick bamboo 22, and the heat transfer heats the material in the spiral cylinder section of thick bamboo 22. Compare in the pyrolysis cylinder of current straight tube-shape, the heat transfer area of spiral cylinder section 22 in this application increases greatly to improve pyrolysis apparatus's heat transfer efficiency and heat utilization rate, more be favorable to going on of pyrolysis reaction.

As shown in fig. 6, the heating cartridge 4 is optimized, and in the present embodiment, the heating cartridge 4 is a combustion cartridge for generating hot gas by burning energy. Specifically, the combustion cylinder body is provided with an observation port 42, an ignition port 43, a gas inlet/outlet 41, and a waste outlet 44. The combustion cylinder is used for burning energy substances such as liquid energy substances, solid energy substances and the like, the generated heating gas enters the spiral space 221 through the vent holes 241 on the support sleeve 24, and the waste materials remaining after the combustion are discharged out of the combustion cylinder through the waste material outlet 44. The gas inlet/outlet 41 is used for gas discharge from the combustion cylinder and external gas intake. The ignition port 43 is used for igniting the source substance in the combustion cylinder. The observation port 42 is used for observing the combustion condition in the combustion cylinder.

Of course, besides the combustion cylinder, the heating cylinder 4 may also be provided with an electric heating device inside the heating cylinder 4 for heating the gas inside the heating cylinder 4, and the heated gas enters the spiral cylinder section 22 for heating. Or the heating cylinder 4 is communicated with an external hot gas source and is used for introducing hot gas into the heating cylinder 4. The gas in the heating cylinder 4 is not limited to the form of the heating cylinder 4 given in the embodiments of the present application as long as the gas can be heated and the heat can be transferred to the spiral cylinder section 22.

In this embodiment, the cracking apparatus further includes a temperature sensor and/or a pressure sensor disposed in the heating cylinder 4 and/or the cracking cylinder 2, the temperature sensor detects the temperature in the heating cylinder 4 and/or the cracking cylinder 2, the pressure sensor detects the pressure in the heating cylinder 4 and/or the cracking cylinder 2, and then the cracking reaction is manually or automatically controlled according to the detected temperature and pressure.

In this embodiment, the cracker cartridge 2 is driven to rotate by the driving device 3, the driving device 3 mainly includes a motor, a speed reducer, a gear ring, a supporting riding wheel and a rotating ring, the rotating ring is preferably arranged on the peripheries of the two ends of the cracker cartridge 2, the supporting riding wheel of the rotating ring through the lower part is rotatably supported, the motor is matched with the gear ring after being decelerated by the speed reducer, the gear ring is fixed on the periphery of one end of the cracker cartridge 2, the gear ring is driven to rotate by the motor, and then the cracker cartridge 2 is driven to rotate. Of course, the driving device 3 may have other configurations, and is not limited to the illustrated embodiment.

In the embodiment, the two ends of the heating cylinder 4 are connected with the outer cylinder walls of the feeding straight cylinder section 21 and the discharging straight cylinder section 23 in a contact friction type rotating and sealing manner. Because the cracking cylinder 2 rotates slowly, the rotary sealing connection of the heating cylinder 4 and the cracking cylinder 2 can be realized through a simple rotary structure. In order to improve the structural strength of the rotary sealing part, the wall thickness of the cracking cylinder 2 is increased at the position of the cracking cylinder 2, which is in contact friction with the heating cylinder 4. Of course, the heating cylinder 4 and the cracking cylinder 2 can also be connected in a rotary sealing manner through other rotary sealing structures.

As shown in fig. 5, the feed end of the cracking cylinder 2 is connected with the feed device 1, the discharge end is connected with the discharge device 7, the feed device 1 and the discharge device 7 are fixed, the feed end of the cracking cylinder 2 is connected with the feed device 1 in a sealing and rotating manner, the discharge end is connected with the discharge device 7 in a sealing and rotating manner, and specifically, the sealing ring 5 is connected in a sealing and rotating manner through the sealing ring 5, and the sealing ring 5 is high temperature resistant. The feeding device 1 is preferably a gas-locking feeding screw, and realizes gas-locking feeding. The feeding device 1 is provided with a material inlet for material entering. The discharging device 7 is an air-locking discharging spiral, a cracking gas outlet port 6 is connected to the wall of the air-locking discharging spiral and used for discharging cracking gas in the cracking cylinder 2, and a discharging port of the air-locking discharging spiral is communicated with the discharging device 8 and used for discharging solid waste in the cracking cylinder 2.

Based on the described schizolysis equipment of above arbitrary embodiment, the embodiment of the utility model provides a still provides a schizolysis system, including drying equipment 9 and schizolysis equipment, the schizolysis equipment is like the described schizolysis equipment of above arbitrary embodiment, and drying equipment 9's material export communicates with the feed arrangement 1 of schizolysis equipment.

During operation, the material is dried through drying equipment 9 earlier, and later, the material after the stoving is discharged from the discharge gate, gets into cracking equipment's feed arrangement 1, sends into the material through feed arrangement 1 and participates in the schizolysis reaction in the schizolysis equipment, and the solid material after the reaction passes through discharge apparatus 7 discharge schizolysis equipment, and the pyrolysis gas that the schizolysis produced goes out port 6 through the pyrolysis gas and discharges. By adopting the cracking equipment, the overall heat transfer efficiency of the cracking system is improved, and the cracking effect is improved.

Further, in this embodiment, the gas inlet and outlet 41 of the heating cylinder 4 of the cracking device is communicated with the drying device 9, and since the waste gas generated in the heating cylinder 4 is high-temperature waste gas, the high-temperature waste gas is introduced into the drying device 9 as heating gas, thereby fully utilizing the waste heat of the cracking system, improving the heat utilization rate and saving the energy consumption.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (11)

1. A cracker cartridge comprising:

a feeding straight cylinder section (21), wherein the feeding straight cylinder section (21) is cylindrical;

the spiral barrel section (22), the spiral barrel section (22) is spiral, one end of the spiral barrel section (22) is fixedly communicated with the feeding straight barrel section (21), a spiral material channel is formed in the spiral barrel section (22), and a spiral space (221) is formed outside the spiral barrel section (22);

the discharging straight cylinder section (23), the discharging straight cylinder section (23) is cylindrical, and the other end of the spiral cylinder section (22) is fixedly communicated with the discharging straight cylinder section (23);

the spiral cylinder section (22) is sleeved with the supporting sleeve (24), a plurality of vent holes (241) are formed in the cylinder wall of the supporting sleeve (24), and the vent holes (241) are communicated with the spiral space (221).

2. The lysis cartridge according to claim 1, wherein the vent holes (241) are helically arranged along the axial direction of the support sleeve (24).

3. The lysis cartridge according to claim 2, wherein the helical direction of the ventilation holes (241) is the same or opposite to the helical direction of the helical cartridge section (22).

4. The cartridge of claim 1, wherein the vent (241) is defined by an orifice plate (242), the orifice plate (242) being secured to the outer wall surface of the support sleeve (24) by an annular seat (244).

5. The cartridge of claim 4, wherein the connection point of the orifice plate (242) and the annular base (244) is further provided with a reinforcement ring plate (243).

6. The cracking drum according to claim 1, characterized in that the support sleeve (24) is fixedly connected with the feeding straight drum section (21) and/or the discharging straight drum section (23).

7. The cracker cartridge of any one of claims 1 to 6, wherein the helical cylindrical section (22) is an annular helical cylindrical section having a hollow configuration at the central axis of the annular helical cylindrical section.

8. A cracking apparatus, comprising a cracking cylinder (2) and a heating cylinder (4), wherein the cracking cylinder (2) is the cracking cylinder (2) as claimed in any one of claims 1 to 7, the two ends of the heating cylinder (4) are respectively sealed and sleeved on the periphery of the feeding straight cylinder section (21) and the discharging straight cylinder section (23) of the cracking cylinder (2), the spiral cylinder section (22) of the cracking cylinder (2) is located in the heating cylinder (4), the interior of the heating cylinder (4) is communicated with the spiral space (221) of the spiral cylinder section (22), and the heating cylinder (4) is relatively fixed and arranged to rotate.

9. The cracking plant according to claim 8, wherein the heating cartridge (4) is a combustion cartridge for burning an energy source to produce hot gases;

or an electric heating device is arranged in the heating cylinder (4) and is used for heating the gas in the heating cylinder (4);

or the heating cylinder (4) is communicated with an external hot gas source and is used for introducing hot gas into the heating cylinder (4).

10. A cracking system comprising a drying apparatus (9) and a cracking apparatus, characterized in that the cracking apparatus is a cracking apparatus according to claim 8 or 9, and the material outlet of the drying apparatus (9) is connected to the feeding device (1) of the cracking apparatus.

11. Cracking system according to claim 10, the gas inlet/outlet (41) of the heating cartridge (4) of the cracking device being in communication with the drying device (9).

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