CN209951833U - Rotary synergistic high-temperature disinfection system - Google Patents

Abstract

The utility model relates to a rotary synergistic high-temperature disinfection system, which comprises a device body and a steam circulation mechanism, wherein the device body is internally provided with a cavity; the bottom of the device body is provided with a steam driving mechanism; the air inlet end of the steam driving mechanism is communicated with the outlet of the steam circulating mechanism, and the air outlet end of the steam driving mechanism is communicated with the interior of the device body; a rotatable tray is arranged in the cavity of the device body; a rotating shaft for transmission is arranged between the steam rotating wheel mechanism and the tray. The tray is driven to rotate by the steam, so that high-temperature steam in the device body can be disturbed, better convection can be formed by the high-temperature steam, the high-temperature steam can better reach the inside of the device with a concave structure, a disinfection dead angle is avoided, and a better disinfection effect is achieved; the high-temperature steam flows sufficiently, the phenomenon of wall hanging is reduced, and the steam residue on the medical instrument can be reduced, so that the residue of pollutants after disinfection is effectively reduced, and the disinfection is more thorough.

Description

Rotary synergistic high-temperature disinfection system

Technical Field

The utility model relates to a medical disinfecting equipment field, concretely relates to rotatory high temperature disinfection system who imitates.

Background

In the medical industry, disinfection tools are essential, and thorough disinfection treatment can effectively prevent the spread of infectious diseases and wound infection of patients, and other possible cross infection. Many medical instruments are sterilized after use in order to be reused.

The steam high-temperature disinfection device is a disinfection device commonly used in medical institutions, but the existing steam disinfection device is generally provided with a corresponding partition plate or a corresponding support in the device, medical instruments to be disinfected are directly placed on the partition plate and the support, and then the medical instruments are heated by the introduced high-temperature steam to achieve the disinfection purpose. However, since the partition or the support is stationary, the medical device itself is stationary during the sterilization process. In some vessel-type medical instruments, especially those with large depth, it is difficult to form high-temperature steam flow and exchange inside the medical instruments, and in such a case, the sterilization effect inside the medical instruments is not ideal, and there is a possibility of large residue.

SUMMERY OF THE UTILITY MODEL

The utility model provides a rotatory synergistic high temperature disinfection system, rotatory through the medical instrument that will be disinfected by high temperature steam, form the flow of air to solve the current fixed high temperature sterilizing equipment and sink in to medical instrument or the not enough problem of indent position disinfection effect.

The utility model adopts the technical scheme as follows:

a rotary synergistic high-temperature disinfection system comprises a device body and a steam circulation mechanism, wherein a cavity is formed in the device body, and an inlet of the steam circulation mechanism is communicated with the interior of the device body; the bottom of the device body is provided with a steam driving mechanism; the air inlet end of the steam driving mechanism is communicated with the outlet of the steam circulating mechanism, and the air outlet end of the steam driving mechanism is communicated with the interior of the device body; a rotatable tray is arranged in the cavity of the device body; a rotating shaft for transmission is arranged between the steam rotating wheel mechanism and the tray.

Further, the steam driving mechanism comprises a shell arranged in the center of the bottom of the device body; a cylindrical cavity is arranged in the middle of the shell; a horizontally arranged steam pump is embedded and fixed in the cavity; a rotating shaft for power output is arranged in the center of the steam pump; the rotating shaft vertically extends upwards into a cavity of the device body so as to be fixedly connected with the ground middle part of the tray; an air inlet pipeline and an air outlet pipeline are horizontally arranged in the shell; one end of the air inlet pipeline is provided with an air inlet opening which is used for being communicated with the steam circulation mechanism on the outer wall of the shell, and the other end of the air inlet pipeline is communicated with an air inlet of the steam pump; one end of the air outlet pipeline is communicated with an air outlet of the steam pump, and an air outlet opening communicated with the interior of the device body is reserved on the upper surface of the shell at the other end of the air outlet pipeline.

Furthermore, a steam pipeline is arranged in the side wall of the device body, and one end of the steam pipeline is communicated with the air outlet opening; the steam pipeline is positioned at one end connected with the air outlet opening and is communicated with the interior of the device body.

Furthermore, a steam dispersing ring with a hollow structure is embedded in the inner wall of the device body; a plurality of air holes are uniformly formed in the side surface of the steam dispersion ring facing the inside of the device body; the steam pipeline is connected to the side wall of the steam dispersion ring, which is provided with the air holes, and is communicated with the inside of the steam dispersion ring.

Furthermore, a sealing ring which is sleeved on the outer wall of the rotating shaft and is in rotating fit with the rotating shaft is fixedly arranged above the part of the device body connected with the rotating shaft.

Furthermore, the setting ring comprises a ring body with a through hole in the center and a plurality of sealing rings which are embedded on the inner wall of the ring body and are horizontally distributed with each other.

Further, the tray comprises a disc body and a baffle ring, wherein the disc body is disc-shaped, the center of the bottom of the tray body is fixedly connected with the top end of the rotating shaft, and the baffle ring is arranged on the upper surface of the disc body and shares a vertical central axis with the disc body; the diameter of the disc body is not larger than that of the cavity of the device body; the disk body and the baffle ring are provided with a plurality of sieve pores for steam to pass through.

Further, the device body comprises a cylinder body with a closed bottom and a pressing cover body arranged above the cylinder body in an openable and closable manner; the cavity is formed between the cylinder body and the gland body.

Furthermore, a heat insulation layer for heat insulation is coated on the outer wall of the cylinder body.

Further, the steam circulation mechanism comprises a steam generator and a steam circulation pipeline connected with the steam generator, wherein the steam generator is arranged independently; the steam circulating pipeline comprises a liquid supply pipe communicated with a liquid supply port of the steam generator and a steam supply pipe connected with a steam supply port of the steam generator; one end of the liquid supply pipe, which is not connected with the steam generator, is communicated with the inside of the device body from the top of the device body; a flow valve and a condenser are sequentially arranged on the liquid supply pipe from the device body to the steam generator; one end of the steam supply pipe, which is not connected with the steam generator, is communicated with the air inlet end of the steam driving mechanism; the steam supply pipe is also provided with a booster pump.

Furthermore, a first check valve is arranged on a pipeline at the joint of the steam supply pipe and the steam generator.

Furthermore, the steam supply pipe between the booster pump and the steam generator is also communicated with an ozone supply mechanism; the ozone supply mechanism comprises an independently arranged ozone generator and an ozone supply pipe which is led out from the ozone generator and is used for supplying ozone; the ozone generator is communicated with the steam supply pipe through the ozone supply pipe.

Still further, a second check valve is arranged on the ozone supply pipe.

To sum up, the utility model discloses compare in prior art's beneficial effect and be:

(1) the tray is driven to rotate by the steam, so that high-temperature steam in the device body can be disturbed, and the high-temperature steam can form better convection; the formed high-temperature steam with convection can better reach the inside of the device with a concave structure, so that a disinfection dead angle is avoided, and a better disinfection effect is achieved; meanwhile, the phenomenon of wall hanging of the fully flowing high-temperature steam is reduced, and the steam residue on the sterilized medical instrument can be reduced, so that the residue of pollutants after sterilization is effectively reduced, and the sterilization degree is improved;

(2) the structure that the supporting plate is pushed to rotate by high-temperature steam is designed, the additional pushing of a motor is not needed, the cost of equipment is saved, and the stability and reliability of the equipment under the condition of using the high-temperature steam are improved;

(3) ozone is introduced into the steam circulation mechanism, so that high-temperature steam is sterilized, and the problem of secondary pollution of medical instruments possibly caused by the high-temperature steam recycled is effectively solved; in addition, the residual ozone molecules can enter the device body and participate in the disinfection of the medical instrument, so that the disinfection means is increased, the disinfection effect is improved, and the waste of ozone resources is reduced;

(4) the ozone suction is completed through the negative pressure generated in the flowing process of the high-temperature steam, no additional supply mechanism is needed, and the ozone gas with corresponding quantity can be automatically supplemented according to the flow of the high-temperature steam, so that the disinfection effect on the high-temperature steam under each flow is ensured;

(5) certain pressure can be formed in the system, so that a high-temperature pressure environment is formed in the device body, and the disinfection effect is further improved.

Drawings

FIG. 1 is a schematic view of a rotary high-temperature sterilization system

FIG. 2 is a schematic horizontal section of the steam driving mechanism of the present invention

Labeled as: 1-gland body, 2-heat insulation layer, 3-cylinder body, 4-baffle ring, 5-disk body, 6-steam dispersion ring, 7-steam pipeline, 8-air outlet pipeline, 9-seating ring, 10-rotating shaft, 11-steam pump, 12-shell body, 13-steam supply pipe, 14-steam generator, 15-booster pump, 16-second check valve, 17-ozone supply pipe, 18-ozone generator, 19-first check valve, 20-condenser, 21-flow valve, 22-liquid supply pipe, 23-vertical through hole and 24-air inlet pipeline.

Detailed Description

All features disclosed in this specification may be combined in any combination, except features and/or steps that are mutually exclusive.

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings and specific embodiments.

Examples

A rotary synergistic high-temperature disinfection system comprises a device body and a steam circulation mechanism, wherein a cavity is formed in the device body, and an inlet of the steam circulation mechanism is communicated with the interior of the device body; the device comprises a device body, a steam driving mechanism, a pump structure and a control device, wherein the bottom of the device body is provided with the steam driving mechanism, the steam driving mechanism is internally provided with the pump structure which can be driven by steam input from the outside and can rotate by the steam driving mechanism to form power output to the outside again, and a micro water pump with less driving force demand can be selected as the pump structure; the air inlet end of the steam driving mechanism is communicated with the outlet of the steam circulating mechanism, and the air outlet end of the steam driving mechanism is communicated with the interior of the device body, so that steam can pass through the steam driving mechanism, push the steam driving mechanism and then enter the device body from the outlet of the steam driving mechanism, and further the cavity in the device body is heated to form a high-temperature disinfection environment; a rotatable tray is arranged in the cavity of the device body; a rotating shaft 10 for transmission is arranged between the steam rotating wheel mechanism and the tray, taking the micro water pump as an example, the rotating shaft 10 penetrates through the shell of the micro water pump and then is fixedly connected with the shaft part of the rotating wheel in the shell, so that when the blades on the rotating wheel rotate under the pushing of steam, torque can be output outwards through the rotating shaft 10 fixedly connected with the rotating wheel, and in the embodiment, the torque output outwards is used for driving the tray connected with the rotating shaft 10 to rotate.

The working principle and the process of the technical scheme are as follows:

the steam circulating mechanism comprises a device for generating high-temperature steam by heating water, the steam generated by the device is transmitted to the steam driving mechanism through a pipeline, and the steam driving mechanism can generate certain steam pressure due to the fact that the volume of the steam is enlarged from the water to the steam, so that a pump structure contained in the steam driving mechanism is pushed to rotate to form torque output. The resulting torque output is further transmitted via the shaft 10 connected to the rotating part of the pump arrangement to the tray for holding the medical devices to be disinfected, thereby driving the tray to start the fitting. And the completion is to the driven steam of pump structure, and the other end of steam actuating mechanism discharges and carries to the inside of device body along the pipeline to heat the inside of device body, and then make the inside of device body form the high temperature disinfection environment. Meanwhile, after the subsequent steam is subjected to the above process and enters the inside of the device body, the gas inside the device body is extruded and discharged, so that the steam entering firstly can be recycled to generate the high-temperature steam device, on one hand, the high-temperature state inside the device body can be maintained through the replacement of the high-temperature steam inside the device body, the disinfection effect is realized, on the other hand, the steam can be circulated, the using amount of the steam is reduced, and the cost is saved.

Compared with the prior art, this embodiment has realized rotating through steam drive tray, can disturb the inside high temperature steam that exists of device body to make high temperature steam form better convection current. The formed high-temperature steam with convection can better reach the inside of the device with the concave structure, thereby avoiding dead angles of disinfection and playing a better role in disinfection. Meanwhile, the phenomenon of wall hanging of the fully flowing high-temperature steam is reduced, and the steam residue on the sterilized medical instrument can be reduced, so that the residue of pollutants after sterilization is effectively reduced, and the sterilization degree is improved.

Preferably, a preferred structure for implementing the steam driving mechanism is provided, specifically: the steam driving mechanism comprises a shell 12 arranged at the center of the bottom of the device body; a cylindrical cavity is arranged in the middle of the shell 12; a steam pump 11 which is horizontally arranged is embedded and fixed in the cavity; a rotating shaft 10 for power output is arranged in the center of the steam pump 11; the rotating shaft 10 vertically and upwardly extends into a cavity of the device body so as to be fixedly connected with the middle part of the ground of the tray; an air inlet pipeline 24 and an air outlet pipeline 8 are horizontally arranged in the shell 12; one end of the air inlet pipeline 24 is provided with an air inlet opening used for being communicated with a steam circulation mechanism on the outer wall of the shell 12, and the other end of the air inlet pipeline is communicated with an air inlet of the steam pump 11; one end of the air outlet pipeline 8 is communicated with an air outlet of the steam pump 11, and an air outlet opening communicated with the interior of the device body is reserved on the upper surface of the shell 12 at the other end of the air outlet pipeline. This steam actuating mechanism is the bottom of independent design and integrated installation and device body, and such benefit lies in can selecting according to the function and be enough needs rotate the tray, simultaneously, has also made things convenient for steam actuating mechanism's dismouting to wash and maintain. In particular, the housing 12 may be a solid plate made of a high temperature and steam corrosion resistant material, in which case the inlet duct 24 and the outlet duct 8 are directly drilled or grooved into the plate; the housing 12 may be a hollow box structure, and the steam pump 11 is fixed in the box structure in a posture that the rotating wheel rotates horizontally, and then serves as the air inlet duct 24 and the air outlet duct 8 through actual ducts, and is connected to an opening structure provided on a corresponding surface of the box structure for communicating with other components.

Furthermore, a steam pipeline 7 is arranged in the side wall of the device body, and one end of the steam pipeline is communicated with the air outlet opening; the steam pipeline 7 is positioned at one end connected with the air outlet opening and is communicated with the interior of the device body; a steam dispersing ring 6 with a hollow structure is embedded in the inner wall of the device body; a plurality of air holes are uniformly formed in the side surface of the steam dispersion ring 6 facing the inside of the device body; the steam pipeline 7 is connected to the side wall of the steam dispersion ring 6 provided with air holes and communicated with the inside of the steam dispersion ring 6. In fact, inside entering steam of device body, can select its bottom surface to go on, also can select the side to go on, but in order to improve the dispersion degree of steam, through setting up steam conduit 7 on the device body lateral wall in this improvement scheme, steam after through steam actuating mechanism is introduced from the side of device body, then disperse steam through steam dispersion ring 6 of being connected with it, and the inside that enters into the device body along the inner wall of device body is the mode of circumference distribution, thereby the even degree of the inside high temperature steam distribution of device body has been improved, the heating effect of high temperature steam to the device body inside has also been strengthened simultaneously, and then the effect to medical instrument has been improved. In addition, because the distribution of steam is more even, in the process that the tray drives the medical instrument to rotate, the probability that each part of the medical instrument is contacted with high-temperature steam can be improved, and therefore the effect of preventing dead angles of disinfection is better achieved. It should be noted that the steam dispersing ring 6 is usually disposed on the inner wall of the device body below the tray, so that the high-temperature steam can better pass through the medical instruments from bottom to top, thereby achieving better disinfection effect.

Furthermore, a setting ring 9 which is sleeved on the outer wall of the rotating shaft 10 and is in rotating fit with the rotating shaft 10 is fixedly arranged above the part of the device body connected with the rotating shaft 10. Because the high-temperature steam has stronger permeability, in order to prevent the high-temperature steam from escaping along the gap at the joint of the rotating shaft 10 and the device body, the setting ring 9 for sealing is arranged according to the above manner, so that the high-temperature steam can be prevented from escaping to a certain extent, and the utilization rate of the high-temperature steam is improved; meanwhile, the high-temperature steam which is dissipated can be prevented from entering the cavity where the steam pump 11 is located, the corrosion of the steam pump 11 is reduced, and the service life of the steam pump 11 is prolonged.

Furthermore, a preferable scheme of the setting ring 9 is provided, which specifically comprises: the seat seal ring 9 comprises a ring body with a through hole in the center and a plurality of seal rings which are embedded on the inner wall of the ring body and are horizontally distributed mutually. It should be noted that, because the high-temperature steam has a certain effect of accelerating aging of the rubber material, in such a case, in order to better achieve the sealing effect, the number of the plurality of seal rings is generally more than 2, and considering balance between cost and effect, the number of the plurality of seal rings is preferably 2 to 3, and most preferably 2.

As a preferred scheme, the present embodiment further provides a preferred tray structure, specifically: the tray comprises a disc-shaped tray body 5 and a baffle ring 4, wherein the center of the bottom of the disc-shaped tray body is fixedly connected with the top end of the rotating shaft 10, and the baffle ring 4 is arranged on the upper surface of the tray body 5 and shares a vertical central axis with the tray body 5; the diameter of the disc body 5 is not larger than that of the cavity of the device body; the disk body 5 and the baffle ring 4 are provided with a plurality of sieve pores for steam to pass through. The tray body 5 is used for bearing medical instruments to be disinfected; meanwhile, as the disc body 5 rotates in the using process, in order to prevent the medical instrument from being thrown out, a corresponding baffle ring 4 is arranged on the disc body 5 for blocking. Simultaneously still be provided with the sieve mesh on disk body 5 and fender ring 4 to let from down up this internal high temperature steam of entering device can pass disk body 5 and keep off ring 4 and by sterile medical instrument fully contact, thereby guarantee high temperature disinfection's effect.

As a preferred scheme, the present embodiment further provides a preferred apparatus body, specifically: the device body comprises a cylinder body 3 with a closed bottom and a gland body 1 which is arranged above the cylinder body 3 in an openable and closable manner; the cavity is formed between the cylinder 3 and the gland body 1. A vertical through hole 23 structure for communicating the cavity in the device body with the steam circulation mechanism is arranged at the central part of the gland body 1; meanwhile, the gland body 1 has a certain thickness, so that the strength of the gland body 1 is improved; in addition, the connection relationship between the gland body 1 and the cylinder body 3 can be generally, but not limited to, a snap connection. It should be noted that, as the pipeline is connected above the gland body 1, the threaded connection is not suitable.

Furthermore, the outer wall of the cylinder 3 is coated with the thermal insulation layer 2 for thermal insulation, which can insulate the device body, so that the inside of the device body can be at a higher temperature, and the obtained disinfection effect is improved.

As a preferable scheme, the embodiment further provides a specific scheme of a steam circulation mechanism for realizing a high-temperature steam circulation, which is as follows: the steam circulation mechanism comprises a steam generator 14 and a steam circulation pipeline connected with the steam generator 14, wherein the steam generator 14 is arranged independently; the steam circulating pipeline comprises a liquid supply pipe 22 communicated with a liquid supply port of the steam generator 14 and a steam supply pipe 13 connected with a steam supply port of the steam generator 14; the end of the liquid supply pipe 22 which is not connected with the steam generator 14 is communicated with the inside of the device body from the top of the device body; a flow valve 21 and a condenser 20 are sequentially arranged on the liquid supply pipe 22 from the device body to the steam generator 14; one end of the steam supply pipe 13, which is not connected with the steam generator 14, is communicated with the air inlet end of the steam driving mechanism; the steam supply pipe 13 is also provided with a booster pump 15. Since the liquid supply tube 22 is connected to the top end of the main body of the apparatus, and the top end of the main body of the apparatus is usually required to be repeatedly opened and closed, the connection with the main body of the apparatus should be a hose structure, and the hose structure should be made of a material resistant to high temperature steam. The working process of the steam circulation structure is that the steam generator 14 converts water added in the steam generator into high-temperature steam in a heating mode, the high-temperature steam is discharged from a steam supply port and firstly passes through the booster pump 15 along the steam supply pipe 13, and the booster pump 15 is a compression pump capable of compressing the volume of the steam and increasing the pressure of the steam pressure; after passing through the booster pump 15, the pressure of the high-temperature steam is increased, so that the driving requirement of the steam driving mechanism is met; after the high-temperature steam drives the steam driving mechanism, the high-temperature steam enters the device body to sterilize medical instruments; since the steam generator 14 will continue to generate high temperature steam, the subsequent steam will cause the high temperature steam in the previous device body to exit from the top of the device body and enter the liquid supply pipe 22. Be provided with flow valve 21 on the feed pipe 22, can realize controlling the flow of high-temperature steam in the feed pipe 22 through flow valve 21 to make this internal high-temperature steam of device can produce certain piling up, and then at the inside certain pressure environment that forms of device body, can further promote high-temperature steam's high temperature state like this, finally make medical instrument can accomplish the disinfection process under high temperature pressure environment, with this effect that has improved high-temperature sterilization. The high-temperature steam flowing through the flow valve 21 is completely liquefied through the heat exchange effect of the condenser 20 and then returns to the steam generation energy mechanism for generating new high-temperature steam, so that the circulation efficiency of the high-temperature steam is improved. This is the pre-operation process of the steam cycle mechanism in the preferred embodiment.

Furthermore, a first check valve 19 is arranged on a pipeline at the connection part of the steam supply pipe 13 and the steam generator 14, so that the output steam can be effectively prevented from returning to the steam generator 14 from the new steam, the subsequent generation of new high-temperature steam is ensured, and the service life of the steam generator 14 is also ensured; meanwhile, the normal operation of the steam circulation is also ensured.

Furthermore, the steam supply pipe 13 between the booster pump 15 and the steam generator 14 is also communicated with an ozone supply mechanism; the ozone supply mechanism comprises an independently arranged ozone generator 18 and an ozone supply pipe 17 which is led out from the ozone generator 18 and is used for supplying ozone; the ozone generator 18 is communicated with the steam supply pipe 13 through the ozone supply pipe 17. Since the steam may come into direct contact with the medical instruments during the sterilization process, certain contaminants, such as pathogens, bacteria, etc., may be entrained during use. In addition, the steam is recycled, and if the steam cannot be treated in time, secondary pollution is caused to medical instruments. Here, set up corresponding confession ozone on supplying steam pipe 13 and take place the mechanism, the negative pressure effect that does the production through the steam circulation extracts a certain amount of ozone and mixes into high temperature steam, then through mixing at the in-process through booster pump 15, the pollutant structure that probably smugglies secretly among ozone molecule and the high temperature steam in the mixing process to carry out the oxidation to the latter and kill the disinfection, thereby guaranteed to enter into the cleanness of the inside high temperature steam of device body, and then avoided secondary pollution. In addition, the concentration of ozone in the generated ozone gas is increased, so that a certain amount of ozone molecules can still be carried in the high-temperature steam entering the device body, and the ozone molecules can further promote the disinfection effect of the medical instrument.

Furthermore, the ozone supply pipe 17 is provided with a second check valve 16, so that high-temperature steam with pressure is prevented from flowing back into the ozone generator 18, the ozone generator 18 is prevented from being damaged by the high-temperature steam, the service life of the ozone generator 18 is prolonged, and the functions of the ozone generator in the system are ensured.

The above-mentioned embodiments only express the specific embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for those skilled in the art, without departing from the technical idea of the present application, several changes and modifications can be made, which are all within the protection scope of the present application.

Claims (10)

1. A rotary synergistic high-temperature disinfection system comprises a device body and a steam circulation mechanism, wherein a cavity is formed in the device body, and an inlet of the steam circulation mechanism is communicated with the interior of the device body; the method is characterized in that: the bottom of the device body is provided with a steam driving mechanism; the air inlet end of the steam driving mechanism is communicated with the outlet of the steam circulating mechanism, and the air outlet end of the steam driving mechanism is communicated with the interior of the device body; a rotatable tray is arranged in the cavity of the device body; a rotating shaft (10) for transmission is arranged between the steam rotating wheel mechanism and the tray.

2. A rotary enhanced thermal sterilization system according to claim 1, wherein: the steam driving mechanism comprises a shell (12) arranged at the center of the bottom of the device body; a cylindrical cavity is arranged in the middle of the shell (12); a steam pump (11) which is horizontally arranged is embedded and fixed in the cavity; a rotating shaft (10) for power output is arranged in the center of the steam pump (11); the rotating shaft (10) vertically extends upwards into a cavity of the device body so as to be fixedly connected with the middle part of the ground of the tray; an air inlet pipeline (24) and an air outlet pipeline (8) are horizontally arranged in the shell (12); one end of the air inlet pipeline (24) is provided with an air inlet opening which is used for being communicated with the steam circulation mechanism on the outer wall of the shell (12), and the other end of the air inlet pipeline is communicated with an air inlet of the steam pump (11); one end of the air outlet pipeline (8) is communicated with an air outlet of the steam pump (11), and an air outlet opening used for being communicated with the interior of the device body is reserved on the upper surface of the shell (12) at the other end of the air outlet pipeline; a steam pipeline (7) with one end communicated with the air outlet opening is vertically arranged in the side wall of the device body; the steam pipeline (7) is positioned at one end connected with the air outlet opening and is communicated with the interior of the device body.

3. A rotary enhanced thermal sterilization system according to claim 2, wherein: a steam dispersing ring (6) with a hollow structure is embedded in the inner wall of the device body; a plurality of air holes are uniformly formed in the side surface of the steam dispersion ring (6) facing the inside of the device body; the steam pipeline (7) is connected to the side wall of the steam dispersion ring (6) for arranging the air holes and is communicated with the inside of the steam dispersion ring (6).

4. A rotary enhanced thermal sterilization system according to claim 1, wherein: a sealing ring (9) which is sleeved on the outer wall of the rotating shaft (10) and is in rotating fit with the rotating shaft (10) is fixedly arranged above the part of the device body connected with the rotating shaft (10); the seat sealing ring (9) comprises a ring body with a through hole in the center and a plurality of sealing rings which are embedded on the inner wall of the ring body and are horizontally distributed mutually.

5. A rotary enhanced thermal sterilization system according to claim 1, wherein: the tray comprises a disc-shaped tray body (5) and a baffle ring (4), wherein the center of the bottom of the disc-shaped tray body is fixedly connected with the top end of the rotating shaft (10), and the baffle ring is arranged on the upper surface of the tray body (5) and shares a vertical central axis with the tray body (5); the diameter of the disc body (5) is not larger than that of the cavity of the device body; the plate body (5) and the retaining ring (4) are provided with a plurality of sieve holes for steam to pass through.

6. A rotary enhanced thermal sterilization system according to claim 1, wherein: the device body comprises a cylinder body (3) with a closed bottom and a gland body (1) which is arranged above the cylinder body (3) in an openable and closable manner; the cavity is formed between the cylinder body (3) and the gland body (1); and a thermal insulation layer (2) for heat insulation is coated on the outer wall of the cylinder body (3).

7. A rotary enhanced thermal sterilization system according to claim 1, wherein: the steam circulation mechanism comprises a steam generator (14) and a steam circulation pipeline connected with the steam generator (14), wherein the steam generator (14) is arranged independently; the steam circulation pipeline comprises a liquid supply pipe (22) communicated with a liquid supply port of the steam generator (14) and a steam supply pipe (13) connected with a steam supply port of the steam generator (14); one end of the liquid supply pipe (22) which is not connected with the steam generator (14) is communicated with the inside of the device body from the top of the device body; a flow valve (21) and a condenser (20) are sequentially arranged on the liquid supply pipe (22) from the device body to the steam generator (14); one end of the steam supply pipe (13) which is not connected with the steam generator (14) is communicated with the air inlet end of the steam driving mechanism; the steam supply pipe (13) is also provided with a booster pump (15).

8. A rotary enhanced thermal sterilization system according to claim 7, wherein: a first check valve (19) is arranged on a pipeline at the joint of the steam supply pipe (13) and the steam generator (14).

9. A rotary enhanced thermal sterilization system according to claim 7, wherein: the steam supply pipe (13) between the booster pump (15) and the steam generator (14) is also communicated with an ozone supply mechanism; the ozone supply mechanism comprises an independently arranged ozone generator (18) and an ozone supply pipe (17) which is led out from the ozone generator (18) and is used for supplying ozone; the ozone generator (18) is communicated with the steam supply pipe (13) through the ozone supply pipe (17).

10. A rotary enhanced thermal sterilization system according to claim 9, wherein: the ozone supply pipe (17) is provided with a second check valve (16).

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