CN215815219U - High-temperature irradiation box for irradiation of electron accelerator - Google Patents

Abstract

The utility model discloses a high-temperature irradiation box for irradiation of an electron accelerator, which comprises a supporting base, an automatic opening and closing protection assembly and an irradiation environment stabilizing assembly, wherein the automatic opening and closing protection assembly is connected and arranged on the supporting base, the irradiation environment stabilizing assembly is connected and arranged inside the automatic opening and closing protection assembly, the automatic opening and closing protection assembly comprises a shell, a supporting plate, a telescopic supporting column, a placing bottom plate, an irradiation window and a connecting flange, and the irradiation environment stabilizing assembly comprises a rotating base, a tray, a heating box, a thermal imaging camera, an air inlet pipe, an air outlet pipe and a thermal imaging display screen. The utility model relates to the technical field of electron accelerator irradiation equipment, in particular to a high-temperature irradiation box for electron accelerator irradiation, which can ensure the stable environment in the irradiation box, well observe the internal irradiation condition, ensure better irradiation reaction effect and adopt a well-protected opening mode after irradiation.

Description

High-temperature irradiation box for irradiation of electron accelerator

Technical Field

The utility model relates to the technical field of electron accelerator irradiation equipment, in particular to a high-temperature irradiation box for electron accelerator irradiation.

Background

The irradiation of high-energy electron beam generated by the electron accelerator can make some substances produce physical, chemical and biological effects, and can effectively kill pathogenic bacteria, viruses and pests. The technology is widely applied to material modification, new material manufacturing, environmental protection, processing production, sterilization and disinfection of medical and sanitary products, food sterilization and fresh-keeping and the like in industrial production, and an electron accelerator irradiation device comprises an electron accelerator and a beam-off device. The accelerator is used for preparing a part for emitting high-energy electron beams, the beam-off device is a part for directly producing, and materials needing irradiation processing are loaded in the beam-off device, the current beam-off device is often in a specially processed irradiation box, and can meet some auxiliary conditions including temperature, gas environment and the like during irradiation processing, while some irradiation boxes cannot form a stable environment in order to meet the purposes of continuous production and efficiency pursuit, while some irradiation boxes with stable environment cannot know the internal conditions in real time during irradiation, cannot master the irradiation process, excessively depend on experience and theory, are over-ideal in reaction, and can possibly cause certain influence on people due to the irradiation allowance when the irradiation box is opened after irradiation is finished.

SUMMERY OF THE UTILITY MODEL

Aiming at the situation and overcoming the defects of the prior art, the utility model provides the high-temperature irradiation box for the irradiation of the electron accelerator, which can ensure the stable environment in the irradiation box, well observe the internal irradiation situation, ensure better irradiation reaction effect and adopt a well-protected opening mode after the irradiation is finished.

The technical scheme adopted by the utility model is as follows: the utility model relates to a high-temperature irradiation box for irradiation of an electron accelerator, which comprises a supporting base, an automatic opening and closing protection assembly and an irradiation environment stabilizing assembly, wherein the automatic opening and closing protection assembly is connected and arranged on the supporting base, the irradiation environment stabilizing assembly is connected and arranged inside the automatic opening and closing protection assembly, the automatic opening and closing protection assembly comprises a shell, a supporting plate, a telescopic supporting column, a placing bottom plate, an irradiation window and a connecting flange, the placing bottom plate is connected and arranged on the supporting base, the telescopic supporting column is vertically arranged on two sides of the placing bottom plate, the supporting plate is connected and arranged at the top end of the telescopic supporting column, the shell is fixedly connected and arranged between the supporting plates and is arranged right above the placing bottom plate, the irradiation window penetrates through the top of the shell, the connecting flange is connected and arranged on the shell and is arranged above the irradiation window, and the irradiation environment stabilizing assembly comprises a rotating base, a rotating shaft and a rotating shaft, a rotating shaft and a rotating shaft are arranged on the rotating shaft, and a shaft is arranged on the rotating shaft, and a shaft is arranged on the rotating shaft, and the rotating shaft is arranged on the rotating shaft, the rotating shaft is rotated by the rotating shaft, and the rotating shaft is rotated by the rotating shaft, and the rotating shaft, the rotating shaft is rotated by the rotating shaft, the rotating shaft is rotated shaft, the rotating shaft is rotated by the rotating shaft, the rotating shaft is rotated by the rotating shaft, and the rotating shaft, the rotating shaft is rotated by the rotating shaft, and the rotating shaft, Tray, intensification box, thermal imaging camera, intake pipe, outlet duct and thermal imaging display screen, the rotating base is connected to be located and is placed on the bottom plate, the tray is placed and is located on the rotating base, the intensification box is connected and is located on the shell inside wall, the thermal imaging camera is connected and is located in the shell on the back wall and the scope covers the tray setting, intake pipe and outlet duct all run through and locate shell top one side, the thermal imaging display screen is connected and is located the shell surface.

Furthermore, each telescopic support column is arranged in a synchronous telescopic mode.

Further, the telescopic stroke of the telescopic support column is set to be higher than the height of the shell.

Furthermore, a sealing strip is bonded at the contact position of the bottom of the shell and the placing bottom plate.

Furthermore, the placing bottom plate is provided with an anti-skid projection connected with the contact position of the shell.

Further, the inner wall of the shell is fully covered with a heat insulation coating.

The utility model with the structure has the following beneficial effects: when the high-temperature irradiation box is used, the telescopic support columns extend, the shell and an electronic accelerator connected to a connecting flange are synchronously jacked up, a bottom plate and a rotating base are exposed and placed, a material to be irradiated is placed on a tray and placed on the rotating base, then the telescopic support columns are lowered, sealing strips at the bottom of the shell are aligned with anti-skidding bulges and are tightly pressed, internal environment gas is replaced through an air inlet pipe and an air outlet pipe, a heating box and a thermal imaging camera are opened, the internal temperature displayed on a thermal imaging display screen is observed, the heating box is closed and the electronic accelerator is opened for irradiation after the internal temperature reaches a standard, the irradiation condition is judged through the temperature change of the thermal imaging display screen reaction, the electronic accelerator is closed after the completion, the shell is automatically lifted by the telescopic support columns, the tray is taken down after the internal environment is stabilized, and therefore, the stability of the internal environment during irradiation can be ensured, meanwhile, irradiation information can be mastered constantly, and the effect is guaranteed.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a high-temperature irradiation chamber for irradiation of an electron accelerator according to the present invention;

FIG. 2 is a front view of a high temperature irradiation chamber for electron accelerator irradiation according to the present invention.

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

Wherein, 1, support the base, 2, the automatic protection subassembly that opens and shuts, 3, the stable subassembly of irradiation environment, 4, the shell, 5, the backup pad, 6, flexible support column, 7, place the bottom plate, 8, the irradiation window, 9, flange, 10, rotating base, 11, the tray, 12, the box that heaies up, 13, thermal imaging camera, 14, the intake pipe, 15, the outlet duct, 16, the thermal imaging display screen, 17, sealing strip, 18, non-skid raised, 19, thermal barrier coating.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in the figure 1-2, the high-temperature irradiation box for electron accelerator irradiation comprises a supporting base 1, an automatic opening and closing protection component 2 and an irradiation environment stabilizing component 3, wherein the automatic opening and closing protection component 2 is connected and arranged on the supporting base 1, the irradiation environment stabilizing component 3 is connected and arranged inside the automatic opening and closing protection component 2, the automatic opening and closing protection component comprises a shell 4, a supporting plate 5, a telescopic supporting column 6, a placing bottom plate 7, an irradiation window 8 and a connecting flange 9, the placing bottom plate 7 is connected and arranged on the supporting base 1, the telescopic supporting column 6 is vertically arranged on two sides of the placing bottom plate 7, the supporting plate 5 is connected and arranged at the top end of the telescopic supporting column 6, the shell 4 is fixedly connected and arranged between the supporting plates 5 and is arranged right above the placing bottom plate 7, the irradiation window 8 penetrates through the top of the shell 4, the connecting flange 9 is connected and arranged on the shell 4 and is arranged above the irradiation window 8, irradiation environmental stabilization subassembly 3 includes rotating base 10, tray 11, intensification box 12, thermal imaging camera 13, intake pipe 14, outlet duct 15 and thermal imaging display screen 16, rotating base 10 is connected and is located on placing bottom plate 7, tray 11 is placed and is located on rotating base 10, intensification box 12 is connected and is located on the shell 4 inside wall, thermal imaging camera 13 is connected and is located in shell 4 on the back wall and the scope covers tray 11 setting, intake pipe 14 all runs through with outlet duct 15 and locates shell 4 top one side, thermal imaging display screen 16 is connected and is located shell 4 surface.

Wherein, each telescopic support column 6 is arranged in a synchronous telescopic way; the telescopic stroke of the telescopic support column 6 is set to be higher than the height of the shell 4; a sealing strip 17 is adhered to the contact position of the bottom of the shell 4 and the placing bottom plate 7; the contact position of the placing bottom plate 7 and the shell 4 is provided with an antiskid lug 18 in a connecting way; the inner wall of the shell 4 is fully covered with a heat insulation coating 19.

When the device is used specifically, the telescopic supporting columns 6 extend, the shell 4 and an electronic accelerator connected to the connecting flange 9 are synchronously jacked up, the bottom plate 7 and the rotating base 10 are placed in an exposed mode, materials needing to be irradiated are placed on the tray 11 and placed on the rotating base 10, the telescopic supporting columns 6 are lowered later, sealing strips 17 at the bottom of the shell 4 are aligned to and pressed against anti-skidding protrusions 18, internal environment gas is replaced through the air inlet pipe 14 and the air outlet pipe 15, the temperature rising box 12 and the thermal imaging camera 13 are opened, the internal temperature displayed on the thermal imaging display screen 16 is observed, the temperature rising box 12 is closed after the standard is reached, the electronic accelerator is opened for irradiation, the irradiation condition is judged according to the temperature change of the thermal imaging display screen 16, the electronic accelerator is closed after the irradiation is completed, the shell 4 is automatically lifted up through the telescopic supporting columns 6, and the tray 11 is taken down after the irradiation is stabilized.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the utility model as defined by the appended claims.

It is noted that, herein, relational terms such as first and second, and the like may be 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.

Claims (6)

1. A high temperature irradiation case that electron accelerator irradiation was used which characterized in that: the irradiation environment stabilizing assembly comprises a rotating base, a tray, a heating box, a thermal imaging camera, an air inlet pipe, an air outlet pipe and a thermal imaging display screen, the rotary base is connected and located on placing the bottom plate, the tray is placed and is located on the rotary base, the box that heaies up is connected and is located on the shell inside wall, the thermal imaging camera is connected and is located on the shell interior back wall and the scope covers the tray setting, intake pipe and outlet duct all run through and locate shell top one side, the thermal imaging display screen is connected and is located the shell surface.

2. A high temperature irradiation chamber for electron accelerator irradiation according to claim 1, characterized in that: each telescopic support column is arranged in a synchronous telescopic manner.

3. A high temperature irradiation chamber for electron accelerator irradiation according to claim 1, characterized in that: the telescopic stroke of the telescopic support column is set to be higher than the height of the shell.

4. A high temperature irradiation chamber for electron accelerator irradiation according to claim 1, characterized in that: and the bottom of the shell is bonded with the contact position of the placing bottom plate to form a sealing strip.

5. A high temperature irradiation chamber for electron accelerator irradiation according to claim 1, characterized in that: the placing bottom plate is provided with an anti-skid bump connected with the contact position of the shell.

6. A high temperature irradiation chamber for electron accelerator irradiation according to claim 1, characterized in that: and the inner wall of the shell is fully covered with a heat insulation coating.

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