阅读说明：本技术 一种液体中低剂量放射性在线测量装置 (On-line measuring device for low-dose radioactivity in liquid ) 是由 邢均儒 于 2020-06-15 设计创作，主要内容包括：本发明公开了一种液体中低剂量放射性在线测量装置,包括罐体,所述罐体的左侧设有进水管,所述进水管的进水口端设有进水阀,所述进水管的上方设有净水冲洗阀,所述进水管与罐体相通,所述罐体的右下方设有出水管,所述出水口端设有排水阀；所述罐体的上方设有开口法兰,所述罐体内设有探测器组件,所述探测器组件的上方安装有导线出线管,所述导线出线管上连接法兰,所述探测器组件通过法兰孔安装在罐体上,所述探测器组件外侧用不锈钢外壳包裹着。本发明提高了探测效率,探测器体积的缩小使得装装置的整个屏蔽层尺寸缩小,降低了成本。(The invention discloses a liquid low-dose radioactivity online measuring device, which comprises a tank body, wherein a water inlet pipe is arranged on the left side of the tank body, a water inlet valve is arranged at the water inlet end of the water inlet pipe, a water purification flushing valve is arranged above the water inlet pipe, the water inlet pipe is communicated with the tank body, a water outlet pipe is arranged at the lower right side of the tank body, and a drain valve is arranged at the water outlet end; the top of the jar body is equipped with the opening flange, the internal detector subassembly that is equipped with of jar, the wire goes out the spool is installed to the top of detector subassembly, flange on the wire goes out the spool, the detector subassembly passes through the flange hole and installs on the jar body, the detector subassembly outside is wrapping up with stainless steel shell. The invention improves the detection efficiency, reduces the size of the whole shielding layer of the device by reducing the volume of the detector and reduces the cost.)

1. The on-line measuring device for the low-dose radioactivity in the liquid is characterized by comprising a tank body, wherein a water inlet pipe is arranged on the left side of the tank body, a water inlet valve is arranged at the water inlet end of the water inlet pipe, a water purification flushing valve is arranged above the water inlet pipe, the water inlet pipe is communicated with the tank body, a water outlet pipe is arranged at the lower right side of the tank body, and a drain valve is arranged at the water outlet end; the top of the jar body is equipped with the opening flange, the internal detector subassembly that is equipped with of jar, the wire goes out the spool is installed to the top of detector subassembly, flange on the wire goes out the spool, the detector subassembly passes through the flange hole and installs on the jar body, the detector subassembly outside is wrapping up with stainless steel shell.

2. The on-line measuring device for low-dose radioactivity in liquid of claim 1, wherein the material of said tank is stainless steel.

3. The on-line measuring device of low-dose radioactivity in liquid of claim 1, wherein the detector assembly is composed of an SiPM photomultiplier and a scintillator, the SiPM is welded on a PCB, a gap between the SiPM and a light removing surface of the scintillator is completely covered by a white light reflecting sheet with the same thickness as the SiPM, a small amount of light-guide silicone oil is coated between the combining surfaces, and finally the light-guide silicone oil and the light reflecting sheet are packaged together by a heat-shrinkable sleeve.

4. The apparatus of claim 1, wherein a water level sensor is further disposed in the tank, the water level sensor is mounted on the detector assembly, and a lead of the water level sensor is discharged through the outlet hole.

5. The in-line low dose radioactivity measuring device of claim 1, wherein the outlet line of said outlet hole is electrically connected to an external display.

6. The on-line measuring device for low-dose radioactivity in liquid according to claim 1, wherein a shielding layer is further disposed outside the tank body.

7. The on-line low-dose radioactivity measuring device of claim 1, wherein the shielding layer is made of lead.

8. The on-line measuring device for low-dose radioactivity in liquid according to claim 4, wherein said shielding layer is further provided with an outlet hole.

Technical Field

The invention relates to the technical field of measuring devices, in particular to a low-dose radioactivity online measuring device in liquid.

Background

Disclosure of Invention

The invention mainly solves the technical problems in the prior art, thereby providing the on-line measuring device for the low-dose radioactivity in the liquid, reducing the size of the whole measuring device, and improving the stability: compared with the traditional photomultiplier, the SiPM photomultiplier has the advantages that the size is greatly reduced, the working high voltage is not needed, the size and the weight of a lead shielding case in the whole device are greatly reduced, and meanwhile, the stability is greatly improved.

The technical problem of the invention is mainly solved by the following technical scheme:

the liquid low-and-medium-dose radioactivity online measuring device comprises a tank body, wherein a water inlet pipe is arranged on the left side of the tank body, a water inlet valve is arranged at the water inlet end of the water inlet pipe, a water purification flushing valve is arranged above the water inlet pipe, the water inlet pipe is communicated with the tank body, a water outlet pipe is arranged at the lower right side of the tank body, and a drain valve is arranged at the water outlet end; the top of the jar body is equipped with the opening flange, the internal detector subassembly that is equipped with of jar, the wire goes out the spool is installed to the top of detector subassembly, flange on the wire goes out the spool, the detector subassembly passes through the flange hole and installs on the jar body, the detector subassembly outside is wrapping up with stainless steel shell.

Preferably, the tank body is made of stainless steel.

Preferably, the detector assembly is formed by combining an SiPM photomultiplier and a scintillator, the SiPM is welded on a PCB, a gap between the SiPM and a light removing surface of the scintillator is completely covered by a white light reflecting sheet with the same thickness as the SiPM, little light guide silicone oil is coated between combined surfaces, and finally the SiPM and the light removing surface are packaged together by a heat-shrinkable sleeve.

Preferably, a water level sensor is further arranged in the tank body, the water level sensor is mounted on the detector assembly, and a lead of the water level sensor is discharged through the outlet hole.

Preferably, the outlet wire of the outlet hole is electrically connected with an external display.

Preferably, the tank body is also provided with a shielding layer outside.

Preferably, the shielding layer is made of lead.

Preferably, the shielding layer is further provided with an outlet hole.

The on-line measuring device for the low-dose radioactivity in the liquid has the advantages that: compared with the traditional photomultiplier, the SiPM photomultiplier has the advantages that the size is greatly reduced, the working high voltage is not needed, and therefore the size of a detector in the whole device is greatly reduced, the size and the weight of a lead shielding case are reduced, the cost is reduced, and the stability of the device is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings 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 some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an on-line measuring device for low-dose radioactivity in a liquid according to the present invention;

FIG. 2 is a schematic view of a detector assembly of the present invention;

1. a tank body, 2 water inlet pipes, 3 water inlet valves, 4 purified water flushing valves, 5 water outlet pipes, 6 water outlet valves,

7. Detector assembly, 8 flange, 9 shielding layer, 10 wire outlet hole, 7-1 PCB circuit board,

7-2 SiMP photomultiplier, 7-3 white reflector, 7-4 scintillator, 7-5 water level sensor,

11. The wire emerges from the tube.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present invention can be more easily understood by those skilled in the art, and the scope of the present invention will be more clearly and clearly defined.

As shown in fig. 1-2, the online measuring device for low-dose radioactivity in liquid comprises a tank body 1, wherein a water inlet pipe 2 is arranged on the left side of the tank body 1, a water inlet valve 3 is arranged at the water inlet end of the water inlet pipe 2, a water purification flushing valve 4 is arranged above the water inlet pipe 2, the water inlet pipe 2 is communicated with the tank body 1, a water outlet pipe 5 is arranged at the lower right of the tank body 1, and a water discharge valve 6 is arranged at the water outlet end; the top of the jar body 1 is equipped with opening flange 8, be equipped with detector assembly 7 in the jar body 1, wire outlet pipe 11 is installed to detector assembly 7's top, flange 8 is gone up to wire outlet pipe 11, detector assembly 7 passes through the flange hole and installs on jar body 1, detector assembly 7 outside is wrapping up with the stainless steel shell.

Jar body 1 material is stainless steel, can play corrosion-resistant, waterproof function.

A water level sensor 7-5 is further arranged in the tank body 1, the water level sensor 7-5 is mounted on the detector assembly, and a lead of the water level sensor 7-5 is mounted on the lead appearing pipe and then discharged through the wire outlet hole.

The lead of the detector component 7 and the lead of the water level sensor 7-5 are both discharged out of the tank body 1 through the wire outlet hole 10 and connected with an external display, and the water level and the measurement data in the tank body 1 can be clearly seen through the display.

The detector assembly 7 is formed by combining a 7-2SiPM photomultiplier 7-1 and a scintillator 7-4, the SiPM is welded on a PCB 7-1, a gap between light removing surfaces of the SiPM-2 and the scintillator 7-4 is completely covered by a white light reflecting sheet 7-3 with the same thickness as the SiPM, a small amount of light-guide silicone oil is coated between the combining surfaces, and finally the light-guide silicone oil and the light-guide silicone oil are packaged together by a heat-shrinkable sleeve.

Jar body 1 outside package has shielding layer 9, shielding layer 9's effect: because certain environment background radiation exists in the earth environment, when the radiation value of a measured sample is very low, the radiation of the environment background can interfere with a measured value, and therefore a lead shielding layer is needed to reduce the interference of the environment background radiation on a measurement result.

When the measuring device works, firstly, a sample to be measured flows into the tank body 1 through the water inlet valve, when the tank body 1 is filled with the sample to be measured, the water inlet valve 3 is closed, the water level can be observed through data measured by the water level sensor 7-5, the detector assembly 7 is started to measure and sample, the size of the radiation activity of the sample to be measured is calculated after sampling is finished, the radiation activity is checked through the display, after the sample is detected, the water drainage valve is opened, the sample in the container is emptied, the purified water valve is opened to wash the inside of the container, and preparation is made for next measurement.

The on-line measuring device for the low-dose radioactivity in the liquid has the advantages that: compared with the traditional photomultiplier, the SiPM photomultiplier has the advantages that the size is greatly reduced, the working high voltage is not needed, and therefore the size of a detector in the whole device is greatly reduced, the size and the weight of a lead shielding case are reduced, the cost is reduced, and the stability of the device is improved.

The design concept of the present invention is described above with only one embodiment, and the present invention can be expanded to connect more function modules externally at the same time when the system allows, thereby expanding the functions of the present invention to the maximum.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.