CN217407676U - A fault disappears and kills storehouse for cold chain food - Google Patents

Abstract

The utility model belongs to the technical field of radiation killing, in particular to a fault killing bin for cold chain food, which is provided with a radiation isolation chamber and a killing article transmission line, wherein the radiation isolation chamber is provided with a first ionization radiator and a second ionization radiator for performing radiation killing on articles, the killing article transmission line sequentially passes through the first ionization radiator and the second ionization radiator, the killing article transmission line is used for transmitting articles to be killed, so that the first ionization radiator performs radiation killing on one side of the articles, the second ionization radiator performs radiation killing on the other side of the articles, thereby realizing fault killing on the articles, the fault killing also refers to the articles as an upper half and a lower half, the first ionization radiator can penetrate through the upper half of the articles to kill, the second ionization radiator can penetrate through the lower half of the articles to kill, thereby the killing is more thorough, and the killing effect is better.

Description

A fault disappears and kills storehouse for cold chain food

Technical Field

The utility model belongs to the technical field of the irradiation disappears and kills, concretely relates to fault disappears and kills storehouse for cold chain food.

Background

Places such as epidemic prevention, customs security inspection and the like often need to be disinfected and killed, and as viruses are attached to the articles to spread, a plurality of articles need to be disinfected and killed; in customs, cross-border goods must be killed to prevent entry of viruses, harmful organisms and the like.

In cold chain foods, the temperature conditions are particularly suitable for virus attachment and survival, so that the cold chain foods are very necessary to be sterilized. The cold chain food is generally sterilized by radiation, that is, by ionization, microwave, ultraviolet ray, X-ray, gamma ray, etc. are generated, wherein the microwave kills microorganisms by heat, which is not suitable for cold chain food, the ultraviolet ray is suitable for surface killing, and the X-ray and gamma ray are suitable for penetration killing of wrapped cold chain goods.

In the existing sterilization work, when an article is irradiated by an ionizing irradiator, due to the limitation of the radiation penetration range, only a partial area of the article can be sterilized frequently, and the whole sterilization effect cannot be achieved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a fault disappears and kills storehouse for cold chain food solves among the prior art and kills insufficient technical problem to eliminating of cold chain food.

In order to solve the technical problem, the utility model discloses a following technical scheme:

there is provided a fault killing bin for cold chain food products comprising:

the radiation isolation chamber is internally provided with a first ionization radiator and a second ionization radiator which are used for irradiating and killing articles;

the sterilizing article conveying line sequentially passes through the first ionizing radiator and the second ionizing radiator, and is used for conveying articles to be sterilized, so that the first ionizing radiator irradiates one side of the articles to be sterilized, and the second ionizing radiator irradiates the other side of the articles to be sterilized, and accordingly fault sterilization of the articles is achieved.

Preferably, a sterilizing article turning device is arranged in a section of the sterilizing article conveying line between the first ionization radiator and the second ionization radiator, so that after the first ionization radiator irradiates and sterilizes one side of an article, the second ionization radiator can irradiate and sterilize the other side of the article again.

Preferably, the radiation isolation room comprises an upper space and a lower space, the ionizing radiator is arranged in the upper space, the sterilization article conveying line is arranged in the lower space, and an irradiation hole is formed in the isolation plate between the upper space and the lower space, so that the ionizing radiator in the upper space irradiates and sterilizes the articles on the sterilization article conveying line in the lower space through the irradiation hole.

Preferably, a lower access communicated with the lower-layer space is arranged at the lower part of the radiation isolation chamber, a middle isolation wall is arranged in the lower access, a conveying line inlet and a conveying line outlet are respectively arranged at two sides of the middle isolation wall, and the sterilizing article conveying line enters and exits the lower-layer space through the lower access; and a first radiation isolation wall is arranged at the rear side of the lower access in the lower layer space, and the sterilizing article conveying line passes by the rear side of the first radiation isolation wall in a winding manner, so that the first ionizing radiator and the second ionizing radiator irradiate and sterilize articles on the sterilizing article conveying line at the rear side of the first radiation isolation wall.

Preferably, an upper entrance communicated with the upper space is arranged at the upper part of the radiation isolation chamber, and a second radiation isolation wall is arranged in the upper space and behind the upper entrance, so that the first ionizing radiator and the second ionizing radiator are arranged in the inner side area of the second radiation isolation wall.

Preferably, spare part chambers for storing spare parts are respectively arranged at two sides in front of the lower layer space of the radiation isolation chamber, and a channel for passing in and out a sterilized article conveying line is arranged between the spare part chambers at the two sides;

two first equipment rooms and a control room are arranged on the front side of the upper space of the radiation isolation room, and the first equipment rooms are respectively used for arranging a charging cabinet, a discharging cabinet and a frequency conversion cabinet which correspond to the first ionization radiator and the second ionization radiator; the control chamber is used for arranging a control cabinet which correspondingly controls the first ionization radiator and the second ionization radiator to work;

the rear of the lower layer space of the radiation isolation chamber is provided with a second equipment chamber, the water cooling units of the first ionization radiator and the second ionization radiator are arranged in the second equipment chamber, and an air shaft is arranged on one side of the second equipment chamber.

Preferably, the first ionization radiator and the second ionization radiator are respectively provided with a scanning box in a matching manner, the upper space is divided into a first isolation space and a second isolation space by a partition wall, and the scanning boxes of the first ionization radiator and the second ionization radiator are respectively arranged in the first isolation space and the second isolation space; four hoisting I-shaped steels are pre-embedded at the top of the upper space and are respectively used for installing the first ionization radiator, the second ionization radiator and the matched scanning box.

Preferably, a sewage treatment interlayer is arranged on the inner side of the radiation isolation chamber, and a water inlet and a water outlet communicated with the sewage treatment interlayer are arranged outside the radiation isolation chamber.

Preferably, a third ionizing radiator is further arranged in the radiation isolation chamber, the first ionizing radiator and the second ionizing radiator can radiate downwards above the sterilizing article conveying line, and the third ionizing radiator can radiate upwards below the sterilizing article conveying line.

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

1. this a fault killing storehouse for cold chain food is equipped with radiation isolation room and the article conveyer line of killing, be equipped with in the radiation isolation room and be used for carrying out the first ionization radiator that the radiation killed, the second ionization radiator, the article conveyer line of killing passes through first ionization radiator in proper order, the second ionization radiator, the article conveyer line of killing is used for conveying the article of waiting to kill, make first ionization radiator carry out the radiation to one side of article and kill, the second ionization radiator is used for carrying out the radiation to the opposite side of article and kills, thereby realize carrying out the fault killing to the article, here fault killing also be exactly regards as upper and lower two halves with the article, first ionization radiator can pierce through the killing to the upper half of article, the second ionization radiator can pierce through the killing to the latter half of article, thereby the killing is more thorough, the effect of killing is better.

2. The fault sterilization adopted by the fault sterilization bin for the cold chain food is a novel cold chain food sterilization, preservation and corrosion prevention technology, has the advantages of thorough sterilization, simplicity, rapidness, no chemical residues and no need of fumigation and heating, and is particularly suitable for the sterilization of the cold chain food.

3. The fault sterilizing bin for the cold chain food adopts distributed multiple points to sterilize the articles in different directions, thoroughly solves the defects that the penetration force of electron beam rays is weak and the deep sterilizing of frozen food in an instant compartment can not be completed at one time, realizes deep irradiation coverage of cold chain food packaging, can carry out quantitative, timed, directional and fixed-point accurate irradiation on the cold chain food through electron beam irradiation penetration waves, can instantaneously destroy and oxidize a microorganism and virus DNA system, destroys a microorganism molecular structure, kills harmful virus bacteria efficiently and quickly, increases the freshness of the food, prolongs the shelf life, and prevents the phenomena of growth of insects, mildew, rot and the like of the products. The fault sterilizing bin for cold chain food is particularly suitable for centralized supervision, sterilization and disinfection of the cold chain food in customs.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a top view of an embodiment of the fault killing bin for cold chain food of the present invention.

Fig. 2 is a sectional view taken along line J-J of fig. 1.

Fig. 3 is a schematic view of the arrangement of the apparatus from the perspective of fig. 2.

Fig. 4 is a sectional view taken along line a-a of fig. 2.

Fig. 5 is a schematic view of the arrangement of the apparatus from the perspective of fig. 4.

Fig. 6 is a cross-sectional view B-B of fig. 2.

Fig. 7 is a cross-sectional view taken along line C-C of fig. 2.

Fig. 8 is a schematic view of the arrangement of the apparatus from the perspective of fig. 7.

Fig. 9 is a cross-sectional view E-E of fig. 2.

Fig. 10 is a schematic view of the arrangement of the apparatus from the perspective of fig. 9.

Fig. 11 is a side view F-F of fig. 2.

Fig. 12 is a schematic structural view of a turning device in an embodiment of the fault sterilizing bin for cold chain food of the present invention.

Fig. 13 is a schematic view of the internal structure of an embodiment of the fault sterilizing bin for cold chain food of the present invention.

Fig. 14 is a cross-sectional view taken along line K-K of fig. 13.

Detailed Description

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.

Example 1:

a fault killing bin for cold chain food, please refer to fig. 1-11.

As shown in figure 1, the fault sterilizing bin for cold chain food comprises a radiation isolation chamber 1, wherein the peripheral walls and the top plate of the radiation isolation chamber 1 are poured by concrete, and lead plates are laid to play a role in isolating radiation.

As shown in fig. 8 and 10, a first ionization radiator 2 and a second ionization radiator 3 for radiation sterilization of articles are arranged in the radiation isolation chamber 1, the first ionization radiator 2 and the second ionization radiator 3 are respectively used for generating radiation sterilization rays, and the first ionization radiator 2 and the second ionization radiator 3 are commercially available complete equipment.

As shown in fig. 5, the fault sterilizing bin for cold chain food further comprises a sterilizing article conveying line 4, the sterilizing article conveying line 4 adopts a conveying belt, and as shown in fig. 10, the sterilizing article conveying line 4 sequentially passes through a first ionization radiator 2 and a second ionization radiator 3, the sterilizing article conveying line 4 is used for conveying articles to be sterilized, so that the first ionization radiator 2 performs irradiation sterilization on one side of the articles, the second ionization radiator 3 performs irradiation sterilization on the other side of the articles, and the articles are subjected to fault sterilizing, wherein the fault sterilizing refers to the articles as an upper half and a lower half, the first ionization radiator 2 can perform penetration sterilization on the upper half of the articles, and the second ionization radiator 3 can perform penetration sterilization on the lower half of the articles.

Referring to fig. 5 and 10, in the present embodiment, a sterilizing article turning device 41 is disposed in a section of the sterilizing article conveying line 4 between the first ionizing radiator 2 and the second ionizing radiator 3, and the sterilizing article turning device 41 can turn over all articles conveyed by the sterilizing article conveying line 4, so that the second ionizing radiator 3 can perform irradiation sterilization on the lower half of the article after the first ionizing radiator 2 performs irradiation sterilization on the upper half of the article.

As shown in fig. 2, the radiation isolation room 1 includes an upper space 11 and a lower space 12, and steps are provided on both sides of the lower space 12. As shown in fig. 10, the first ionization radiator 2 and the second ionization radiator 3 are disposed in the upper space 11, and the sterilizing article transfer line 4 is disposed in the lower space 12, and as shown in fig. 9, two irradiation holes 131 are provided in the partition plate 13 between the upper space 11 and the lower space 12, so that the first ionization radiator 2 and the second ionization radiator 3 in the upper space 11 perform irradiation sterilization of the articles on the sterilizing article transfer line 4 in the lower space 12 through the respective irradiation holes 131.

Referring to fig. 4, a lower entrance communicating with the lower space 12 is provided at a lower portion of the radiation isolation room 1, a middle isolation wall 121 is provided in the lower entrance, a transmission line entrance 122 and a transmission line exit 123 are provided at both sides of the middle isolation wall 121, and as shown in fig. 5, the transmission line 4 of the sterilized article passes through the transmission line entrance 122 and the transmission line exit 123 in the lower entrance and enters the lower space 12. By providing the intermediate partition wall 121, the input portion and the output portion of the sterilized article conveying line 4 are isolated, and the sterilized articles on the sterilized article conveying line 4 and the non-sterilized articles are prevented from being in the same space and cross-propagating viruses which may exist.

As shown in fig. 4 and 5, a first radiation isolation wall 124 is provided in the lower space 12 at the rear side of the lower doorway, the first radiation isolation wall 124 has a radiation isolation function, the sterilizing article conveying line 4 passes around the rear side of the first radiation isolation wall 124, so that the first ionizing radiator 2 and the second ionizing radiator 3 perform radiation sterilization on the articles on the sterilizing article conveying line 4 at the rear side of the first radiation isolation wall 124, and the first radiation isolation wall 124 is provided to perform radiation isolation on the area where the lower doorway is located in the lower space 12, thereby preventing the radiation in the lower space 12 from being reflected back and forth to radiate outside through the lower doorway.

As shown in fig. 7 and 8, the radiation isolation chamber 1 is provided at an upper portion thereof with an upper entrance 111 communicating with the upper space 11, and a second radiation isolation wall 112 is provided in the upper space 11 at a rear side of the upper entrance 111, and the second radiation isolation wall 112 has a radiation isolation function, so that the first and second ionizing radiators 2 and 3 are provided in an inner region of the second radiation isolation wall 112, and radiation in the upper space 11 is prevented from being reflected back and forth through the upper entrance 111 to be radiated to the outside.

As shown in fig. 10, the first ionization radiator 2 is provided with a scanning box 21, the second ionization radiator 3 is provided with a scanning box 31, and the radiation generated by the first ionization radiator 2 and the second ionization radiator 3 is irradiated downwards through the scanning box 21 and the scanning box 31, respectively. As shown in fig. 8 and 9, the upper space 11 is partitioned by a partition wall into a first isolation space 113 and a second isolation space 114, and the scanning cassettes 21 and 31 of the first ionization radiator 2 and the second ionization radiator 3 are respectively disposed in the first isolation space 113 and the second isolation space 114.

As shown in fig. 9, four hoisting i-beams are embedded in the top of the upper space 11, wherein the first i-beam 115 and the second i-beam 116 are arranged transversely, and the first i-beam 115 and the second i-beam 116 are respectively used for hoisting and moving the first ionization radiator 2 and the second ionization radiator 3 during installation; the third I-beam 117 and the fourth I-beam 118 are longitudinally arranged, and the third I-beam 117 and the fourth I-beam 118 are respectively used for hoisting the scanning box 21 and the scanning box 31 during installation.

As shown in fig. 4, 5 and 6, spare part chambers 125 for storing spare parts are respectively provided at both sides in front of the lower space 12 of the radiation isolation chamber 1, a passage for passing in and out a sterilizing article conveying line, that is, a lower access opening is provided between the spare part chambers 125 at both sides, and maintenance parts of a tomographic sterilizing compartment for storing cold chain food are provided in the spare part chambers 125.

As shown in fig. 7 and 8, a first equipment room 14, a first equipment room 15 and a control room 16 are provided in front of the upper space 11 of the radiation isolation room 1, wherein the first equipment room 14 and the first equipment room 15 are respectively used for providing power distribution equipment such as a charging cabinet, a discharging cabinet and a frequency conversion cabinet corresponding to the first ionization radiator 2 and the second ionization radiator 3; the control room 16 is used for setting a control cabinet for correspondingly controlling the first ionization radiator 2 and the second ionization radiator 3 to work, and the charging cabinet, the discharging cabinet, the frequency conversion cabinet and the control cabinet are all corollary equipment of the ionization radiators.

Referring to fig. 5 and 8, a second equipment room 17 is provided behind the lower space 12 of the radiation isolation room 1, the water chiller units of the first ionization radiator 2 and the second ionization radiator 3 are provided in the second equipment room 17, cooling water is supplied to the water chiller units through the water tower 18, an air shaft 171 is provided at one side of the second equipment room 17, and air circulation inside the second equipment room 17 is ensured through the air shaft 171.

Example 2:

a fault killing bin for cold chain food, please refer to fig. 12.

The sterilizing article conveying line of the fault sterilizing bin for the cold chain food adopts a sterilizing article overturning device as shown in fig. 12, the sterilizing article overturning device comprises a rack 411, an overturning frame 414 and a driving motor 416 are arranged on the rack 411, and the overturning frame 414 can be driven to overturn for 180 degrees through the driving motor 416. An upper conveying belt 412 and a lower conveying belt 413 are arranged on the turnover frame 414, a bracket of the upper conveying belt 412 is connected to the turnover frame 414 through a constant pressure cylinder 415, and a bracket of the lower conveying belt 413 is directly fixed on the turnover frame 414. An article sensor is arranged on the rack 411, when an article arrives between the upper conveying belt 412 and the lower conveying belt 413, the other part of the sterilizing article conveying line stops running, the constant-pressure air cylinder 415 drives the upper conveying belt 412 to move downwards, so that the article is clamped between the upper conveying belt 412 and the lower conveying belt 413, then the driving motor 416 drives the turnover frame 414 to turn over for 180 degrees, so that the article between the upper conveying belt 412 and the lower conveying belt 413 turns over for 180 degrees, then, the upper conveying belt 412, the lower conveying belt 413 and the sterilizing article conveying line are started, and the article with the turned over 180 degrees is conveyed forwards continuously.

The embodiment only describes one way of the sterilizing article overturning device in the fault sterilizing bin for the cold chain food, and in other embodiments, other types of sterilizing article overturning devices such as a cross type sterilizing article overturning device, an overturning conveyor belt type sterilizing article overturning device and the like can also be adopted.

Example 3:

a fault killing bin for cold chain food, please refer to fig. 13 and 14.

As shown in fig. 13 and 14, the fault sterilizing bin for cold chain food is further provided with a third ionizing radiator 5 in the radiation isolation chamber 1, the radiation isolation chamber 1 is provided with a space extending to the ground below to install the third ionizing radiator 5, the first ionizing radiator 2, the second ionizing radiator 3 can irradiate downwards above the sterilizing article conveying line 4, and the third ionizing radiator 5 can irradiate upwards below the sterilizing article conveying line.

This a fault disinfection storehouse for cold chain food can adopt first ionization radiator 2, second ionization radiator 3 to kill article, and at this moment, need overturn article through killing article turning device 41 to article.

This a fault disappears and kills storehouse for cold chain food also can adopt first ionizing radiator 2 or second ionizing radiator 3 cooperation third ionizing radiator 5 to disappear and kill the article, then do not need to overturn the article through disappearing and killing article turning device 41 this moment, disappear and kill article turning device 41 and only play the effect of transfer article, or can remove and kill article turning device 41 for it is continuous to disappear and kill article conveyer line 4, and at this moment, first ionizing radiator 2 or second ionizing radiator 3 disappear and kill the upper half of article, and third ionizing radiator 5 disappears and kills the latter half of article.

And a marking machine 6 is also arranged at the position close to the outlet of the sterilized article conveying line 4 and is used for marking the sterilized articles.

As shown in fig. 14, a sewage treatment interlayer 7 is arranged inside the radiation isolation chamber 1, a water inlet 71 and a water outlet 72 communicated with the sewage treatment interlayer 7 are arranged outside the radiation isolation chamber 1, sewage is introduced into the sewage treatment interlayer 7, and the water has the function of repeatedly refracting rays, so that the sewage in the sewage treatment interlayer 7 has the radiation-proof function on one hand, and the sewage in the sewage treatment interlayer 7 can be killed by the rays on the other hand, and particularly when the customs uses the device, the sewage generated by the customs flows into the sewage treatment interlayer 7, so that the sewage can be effectively killed and sterilized.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. A fault killing storehouse for cold chain food, comprising:

the radiation isolation chamber is internally provided with a first ionization radiator and a second ionization radiator which are used for carrying out irradiation disinfection on the articles;

the sterilizing article conveying line sequentially passes through the first ionizing radiator and the second ionizing radiator, and is used for conveying articles to be sterilized, so that the first ionizing radiator irradiates one side of the articles to be sterilized, and the second ionizing radiator irradiates the other side of the articles to be sterilized, and accordingly fault sterilization of the articles is achieved.

2. The tomo-killing cartridge for cold chain food products according to claim 1, wherein a killing article turning device is provided in a section of said killing article conveying line between said first ionizing radiator and said second ionizing radiator, so that after said first ionizing radiator performs irradiation killing on one side of an article, said second ionizing radiator can perform irradiation killing on the other side of the article.

3. The sectional kill bin for cold chain food products of claim 1 wherein: the radiation isolation room comprises an upper space and a lower space, the first ionizing radiator and the second ionizing radiator are arranged in the upper space, the sterilizing article conveying line is arranged in the lower space, and an irradiation hole is formed in the isolation plate between the upper space and the lower space, so that the corresponding ionizing radiator in the upper space passes through the irradiation hole to perform irradiation sterilization on articles on the sterilizing article conveying line in the lower space.

4. The sectional kill bin for cold chain food products of claim 3 wherein: a lower access communicated with the lower layer space is arranged at the lower part of the radiation isolation chamber, a middle isolation wall is arranged in the lower access, a conveying line inlet and a conveying line outlet are respectively arranged at two sides of the middle isolation wall, and the sterilizing article conveying line enters and exits the lower layer space through the lower access; and a first radiation isolation wall is arranged at the rear side of the lower access in the lower layer space, and the sterilizing article conveying line passes by the rear side of the first radiation isolation wall in a winding manner, so that the first ionizing radiator and the second ionizing radiator irradiate and sterilize articles on the sterilizing article conveying line at the rear side of the first radiation isolation wall.

5. The sectional kill bin for cold chain food products of claim 3 wherein: an upper entrance communicated with the upper space is formed in the upper part of the radiation isolation chamber, and a second radiation isolation wall is arranged in the upper space and located on the rear side of the upper entrance, so that the first ionizing radiator and the second ionizing radiator are arranged in the inner side area of the second radiation isolation wall.

6. The fault sterilizing bin for cold chain food as claimed in claim 3, wherein spare parts chambers for storing spare parts are respectively arranged at two sides in front of the lower layer space of the radiation isolation chamber, and a passage for passing in and out the sterilizing article conveying line is arranged between the spare parts chambers at two sides;

two first equipment rooms and a control room are arranged on the front side of the upper space of the radiation isolation room, and the first equipment rooms are respectively used for arranging a charging cabinet, a discharging cabinet and a frequency conversion cabinet which correspond to the first ionization radiator and the second ionization radiator; the control chamber is used for arranging a control cabinet which correspondingly controls the first ionization radiator and the second ionization radiator to work;

the rear of the lower layer space of the radiation isolation chamber is provided with a second equipment chamber, the water cooling units of the first ionization radiator and the second ionization radiator are arranged in the second equipment chamber, and an air shaft is arranged on one side of the second equipment chamber.

7. The sectional kill bin for cold chain food products of claim 3 wherein: the first ionization radiator and the second ionization radiator are respectively provided with a scanning box in a matching way, the upper space is divided into a first isolation space and a second isolation space by a separation wall, and the scanning boxes of the first ionization radiator and the second ionization radiator are respectively arranged in the first isolation space and the second isolation space; four hoisting I-shaped steels are pre-embedded at the top of the upper space and are respectively used for installing the first ionization radiator, the second ionization radiator and the matched scanning box.

8. The sectional kill bin for cold chain food products of claim 1 wherein: the radiation isolation chamber is internally provided with a sewage treatment interlayer, and the radiation isolation chamber is externally provided with a water inlet and a water outlet which are communicated with the sewage treatment interlayer.

9. The sectional kill bin for cold chain food products of claim 1 wherein: and a third ionizing radiator is further arranged in the radiation isolation chamber, the first ionizing radiator and the second ionizing radiator can irradiate downwards above the killing article conveying line, and the third ionizing radiator can irradiate upwards below the killing article conveying line.

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