阅读说明：本技术 一种用于微型氢火焰离子化检测器的喷嘴组件 (Nozzle assembly for miniature hydrogen flame ionization detector ) 是由 耿旭辉 关亚风 李盛红 高岩 于 2018-07-24 设计创作，主要内容包括：本发明提供一种微型氢火焰离子化检测器的喷嘴组件,由喷嘴、引管、上密封件、套管、下密封件、上压体、下压体及检测器体组成。上压体的下表面、下压体的上表面和套管的上下表面分别设有圆锥形环形刃口,压紧过程中,四个圆锥形环形刃口分别嵌入上密封件和下密封件的上下表面,实现嵌入式密封；同时圆锥形环形刃口在嵌入过程中向内挤压上下密封件,使其内孔变小从而将引管挤住,最终密封氢气腔、空气腔和上下密封件的内孔与引管外径处的接触缝隙。本发明的喷嘴组件具有以下优点：密封的机械结构简单、紧凑、更可靠；减小燃烧室的死体积,空气流更稳定,使得μ-FID噪声更小；聚酰亚胺或Vespel锥形卡套保证在350℃以下稳定的绝缘和耐压密封性能。(The invention provides a nozzle component of a miniature hydrogen flame ionization detector, which consists of a nozzle, a guide pipe, an upper sealing element, a sleeve, a lower sealing element, an upper pressing body, a lower pressing body and a detector body. The lower surface of the upper pressing body, the upper surface of the lower pressing body and the upper and lower surfaces of the sleeve are respectively provided with a conical annular cutting edge, and in the pressing process, the four conical annular cutting edges are respectively embedded into the upper and lower surfaces of the upper sealing piece and the lower sealing piece to realize embedded sealing; meanwhile, the upper sealing piece and the lower sealing piece are inwards extruded by the conical annular cutting edge in the embedding process, so that the inner hole of the conical annular cutting edge is reduced, the guide pipe is extruded, and finally, the contact gaps between the inner holes of the hydrogen cavity, the air cavity and the upper and lower sealing pieces and the outer diameter of the guide pipe are sealed. The nozzle assembly of the present invention has the following advantages: the sealed mechanical structure is simple, compact and more reliable; the dead volume of the combustion chamber is reduced, the air flow is more stable, and the mu-FID noise is smaller; the polyimide or Vespel taper ferrule ensures stable insulation and pressure tight sealing performance below 350 ℃.)

1. A nozzle assembly for a miniature hydrogen flame ionization detector, comprising: comprises a nozzle (1), a guide tube (2), an upper sealing element (3), a sleeve (4), a lower sealing element (5), an upper pressure body (6), a lower pressure body (7) and a detector body (8) which are coaxially arranged; the nozzle (1) and the guide pipe (2) are respectively straight-through circular pipes with two open ends; the upper sealing element (3) and the lower sealing element (5) are cylinders provided with through holes along the axis, the lower sealing element (5) comprises an upper end cylinder A and a lower end cylinder B which are coaxially arranged, the diameter of the lower end cylinder B is smaller than that of the upper end cylinder A, the upper end cylinder A and the lower end cylinder B form a coaxial T-shaped cylinder, the diameters of the through holes formed in the upper parts of the upper sealing element (3), the upper end cylinder A and the lower end cylinder B along the axis are the same, the diameter of the through hole formed in the lower part of the lower end cylinder B along the axis is smaller than that of the through hole formed in the upper part communicated with the upper part of the lower end cylinder B along the axis, namely, an annular step is formed at the through hole in the lower end cylinder B, and;

the detector body (8) is of a hollow structure provided with a circular through hole from top to bottom, and the upper end surface and the lower end surface of the detector body are provided with threaded holes; an upper pressure body (6) and a lower pressure body (7) which are provided with through holes coaxial with the circular through hole are respectively arranged at the upper opening end and the lower opening end of the circular through hole of the detector body (8), a circular protrusion coaxial with the through hole is arranged at the periphery of the circular through hole at the lower end of the upper pressure body (6), the lower circular protrusion extends into the circular through hole of the detector body (8) from the upper opening end of the circular through hole of the detector body (8), an upper circular protrusion coaxial with the through hole is arranged at the periphery of the circular through hole at the upper end of the lower pressure body (7), and the upper circular protrusion extends into the circular through hole of the detector body (8) from the lower opening end of the circular through hole of;

the lower tubular end of the nozzle (1) is inserted into the upper opening end of the guide tube (2), the nozzle (1) and the guide tube (2) are arranged in the circular through holes of the upper pressure body (6), the lower pressure body (7) and the detector body (8), and the nozzle (1) and the guide tube (2) are coaxially arranged with the circular through hole of the detector body (8); through holes on an upper sealing element (3) and a lower sealing element (5), an upper sealing element (3), a sleeve (4) and the lower sealing element (5) are sequentially sleeved on the outer wall surface of a guide tube (2) in a detector body (8) in a penetrating manner from top to bottom, the lower end surface of the guide tube (2) is abutted against an annular step of the through hole in a lower end cylinder B, and the lower end surface of the upper sealing element (3) and the upper end surface of the lower sealing element (5) are respectively abutted against and contacted with the upper end surface and the lower end surface of the sleeve (4); a through hole is arranged on the side wall surface of the middle part of the detector body (8), and the contact pin (10) penetrates through the through hole to be abutted against the outer wall surface of the sleeve (4);

the lower surface of the upper pressing body (6), the upper surface of the lower pressing body (7) and the upper and lower surfaces of the sleeve (4) are respectively provided with an annular cutting edge (9), and the upper pressing body (6) and the lower pressing body (7) are tightly pressed with the detector body (8) through a threaded hole by a screw (11); in the compressing process, the four annular cutting edges (9) are respectively embedded into the upper surface and the lower surface of the upper sealing element (3) and the lower sealing element (5) to realize embedded sealing; meanwhile, the annular cutting edge (9) extrudes the upper sealing element (3) and the lower sealing element (5) inwards in the embedding process, so that the inner hole of the upper sealing element is reduced, the guide pipe (2) is extruded, and extrusion sealing is realized; finally sealing a hydrogen gas cavity (12) at the lower circular through hole of the lower pressing body (7), an air cavity (13) at the upper circular through hole of the upper pressing body (6) and contact gaps between the inner through holes of the upper and lower sealing pieces and the outer wall of the guide pipe (2).

2. The nozzle assembly of claim 1, wherein: the nozzle (1), the guide pipe (2) and the sleeve (4) are made of metal; the upper sealing member (3) and the lower sealing member (5) are made of polyimide or Vespel or other materials which are high temperature resistant and have the insulation resistance of more than 10¹⁰An ohmic polymer material.

3. The nozzle assembly of claim 1, wherein: the inner diameter of the nozzle (1) is 0.05-0.3 mm, and the outer diameter is 0.3-0.79 mm; the inner diameter of the guide pipe (2) is 0.4-0.8 mm, the outer diameter is 0.8-2.0 mm, the length is 15-35 mm, the length of the nozzle (1) inserted into the guide pipe (2) is 3-5 mm, and the contact gap between the nozzle and the guide pipe is sealed in a welding mode.

4. The nozzle assembly of claim 1, wherein: the upper end of the guide pipe (2) extends out of or is 0.5-2.5 mm higher than the upper end surface of the upper sealing element (3), the guide pipe (2) is inserted into the lower sealing element (5) for 7-8 mm, and the guide pipe is in clearance fit or close contact fit with inner holes of the upper sealing element (3) and the lower sealing element (5) before extrusion.

5. The nozzle assembly of claim 1, wherein: the outer diameter of the upper sealing element (3) is 6-10 mm, and the thickness of the upper sealing element is 1-3 mm; the outer diameter of an upper end cylinder A of the lower sealing piece (5) is 6-10 mm, and the thickness of the upper end cylinder A is 1-3 mm.

6. The nozzle assembly of claim 1, wherein: the width and the height of the annular cutting edge (9) are both 0.3-0.6 mm; the diameter of which is specifically optimized according to the dimensions of the other components.

7. The nozzle assembly of claim 1, wherein: the external diameter 5 ~ 7mm of sleeve pipe (4), height 6 ~ 8mm, dimensional design guarantees that it extrudees before with guide pipe (2) for clearance fit or closely paste and connect the cooperation, forms good sealedly with guide pipe (2) after the extrusion, and polarization voltage passes through contact pin (10), sleeve pipe (4) and guide pipe (2) and adds on nozzle (1).

8. The nozzle assembly of claim 1, wherein: the upper pressing body (6), the lower pressing body (7), the detector body (8) and the contact pin (10) are made of metal, preferably stainless steel.

9. The nozzle assembly of claim 1, wherein: the opening end of the through hole at the lower end of the guide tube (2) is a cone frustum-shaped bell mouth.

Technical Field

The invention relates to the technical field of hydrogen flame ionization detectors, in particular to a nozzle assembly of a miniature hydrogen flame ionization detector.

Background

The hydrogen Flame Ionization Detector (FID) is the most widely used detector for gas chromatograph, and uses hydrogen flame as ionization source to ionize the substance to be detected and the generated micro-current is amplified and detected. The outstanding advantage of FIDs is their response to almost all organic compounds, especially their high sensitivity to hydrocarbon compounds (ppb level); the response of the gas flow rate, pressure, temperature and other condition changes is not greatly influenced; the linear range of the FID is up to 6 orders of magnitude, the time constant of the detector is between 2-5ms, and the dead volume is almost zero. Portable micro gas chromatographs are gaining attention for their on-site real-time analysis capabilities. The traditional FID is not suitable for a portable micro gas chromatograph because of large volume, high energy consumption and high working gas consumption, and developed countries are all researching micro hydrogen flame ionization detectors (mu-FID). The structure and the principle of the conventional FID are deeply researched, the reason that combustion air influences the base flow noise is found, the introduction mode of the combustion air and the structure of the detector are redesigned, and the noise level of the detector is effectively restrained; the high field intensity (800V polarization voltage) is adopted to improve the emission density and initial speed of the nozzle particles and inhibit the generation of secondary electrons; the mu-FID has higher sensitivity than the conventional FID, and the gas consumption is reduced by about 70% (Jianwei Wang, Hua Wang, Chunfeng Duan, Yafeng Guan, Micro-flame ionization detector with a novel structure for portable gas chromatography, Talanta,82,1022 and 1026,2010, Guanbai, Wangjiawei, Juju, Xianli, Xianyan, a small hydrogen flame ionization detector, Chinese patent, No. ZL200810229985. X). However, the mu-FID can only work at 200-220 ℃ for a long time due to the material, the mechanical structure and the like. In order to improve the defects, a taper cutting sleeve type sealed nozzle assembly for a miniature hydrogen flame ionization detector is designed in Guanasia wind and the like (Guanasia wind, Gunn Xuhan, Zhang Jian, Chenyang, high rock, a nozzle assembly for a miniature hydrogen flame ionization detector, Chinese invention patent No. ZL201410772021.5), the problems of complicated mechanical structure and no high temperature resistance of the existing mu-FID sealing are improved, and the reliability of a nozzle area is also improved. However, the sleeve-type sealing manner of the upper and lower cones belongs to contact-type 'wire loop sealing', repeated high-low temperature thermal cycling occurs in the long-term use process, and the thermal expansion coefficient of the polyimide/Vespel conical sleeve is different from that of stainless steel, so that the 'sealing wire loop' is possibly loosened, and the sealing is unreliable.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a novel nozzle assembly of a miniature hydrogen flame ionization detector, which can effectively solve the problem of unreliable sealing of the detector under repeated high-temperature and low-temperature circulation and improve the sealing reliability of a nozzle area.

The technical scheme of the invention is as follows:

a nozzle assembly for a miniature hydrogen flame ionization detector, comprising: comprises a nozzle, a guide pipe, an upper sealing element, a sleeve, a lower sealing element, an upper pressing body, a lower pressing body and a detector body which are coaxially arranged; the nozzle and the guide pipe are respectively straight-through circular pipes with two open ends; the upper sealing element and the lower sealing element are cylinders provided with through holes along the axis, the lower sealing element comprises an upper end cylinder A and a lower end cylinder B which are coaxially arranged, the diameter of the lower end cylinder B is smaller than that of the upper end cylinder A, the upper end cylinder A and the lower end cylinder B form a coaxial T-shaped cylinder, the diameters of the through holes formed in the upper parts of the upper sealing element, the upper end cylinder A and the lower end cylinder B along the axis are the same, the diameter of the through hole formed in the lower part of the lower end cylinder B along the axis is smaller than that of the through hole formed in the upper part communicated with the lower end cylinder B along the axis, namely, an annular step is formed at the through hole in the lower end cylinder B, and the opening end of;

the detector body is of a hollow structure provided with a circular through hole from top to bottom, and the upper end surface and the lower end surface of the detector body are provided with threaded holes; an upper pressing body and a lower pressing body which are provided with through holes coaxial with the circular through hole are respectively arranged at the upper opening end and the lower opening end of the circular through hole of the detector body, annular protrusions coaxial with the through hole are arranged at the periphery of the circular through hole at the lower end of the upper pressing body, the lower annular protrusions extend into the circular through hole of the detector body from the upper opening end of the circular through hole of the detector body, upper annular protrusions coaxial with the through hole are arranged at the periphery of the circular through hole at the upper end of the lower pressing body, and the upper annular protrusions extend into the circular through hole of the detector body from the lower opening end of the circular;

the lower tubular end of the nozzle is inserted into the upper opening end of the guide tube, the nozzle and the guide tube are arranged in the circular through holes of the upper pressing body, the lower pressing body and the detector body, and the nozzle and the guide tube are coaxially arranged with the circular through hole of the detector body; an upper sealing element, a sleeve and a lower sealing element are sequentially sleeved on the outer wall surface of the guide tube positioned in the detector body from top to bottom through holes in the upper sealing element and the lower sealing element, the lower end surface of the guide tube is abutted with an annular step of the through hole in the lower end cylinder B, and the lower end surface of the upper sealing element and the upper end surface of the lower sealing element are respectively abutted and contacted with the upper end surface and the lower end surface of the sleeve; the side wall surface of the middle part of the detector body is provided with a through hole, and the contact pin penetrates through the through hole and abuts against the outer wall surface of the sleeve;

the lower surface of the upper pressing body, the upper surface of the lower pressing body and the upper and lower surfaces of the sleeve are respectively provided with an annular cutting edge, and the upper pressing body and the lower pressing body are tightly pressed with the detector body through screw holes by screws; in the compressing process, the four annular cutting edges are respectively embedded into the upper surface and the lower surface of the upper sealing element and the lower sealing element to realize embedded sealing; meanwhile, the annular cutting edge inwards extrudes the upper sealing element and the lower sealing element in the embedding process, so that the inner hole of the upper sealing element and the lower sealing element is reduced, the guide pipe is extruded, and extrusion sealing is realized; finally sealing the hydrogen cavity at the circular through hole at the lower part of the lower pressing body, the air cavity at the circular through hole at the upper part of the upper pressing body and the contact gap between the inner through hole of the upper sealing element and the inner through hole of the lower sealing element and the outer wall of the guide pipe.

The material of the nozzle, the guide pipe and the sleeve is metal; the materials of the upper sealing piece and the lower sealing piece are polyimide, Vespel or other high polymer materials which are high temperature resistant and have the insulation resistance of more than 1010 ohms.

The inner diameter of the nozzle is 0.05-0.3 mm, and the outer diameter of the nozzle is 0.3-0.79 mm; the inner diameter of the guide pipe is 0.4-0.8 mm, the outer diameter of the guide pipe is 0.8-2.0 mm, the length of the guide pipe is 15-35 mm, the length of the guide pipe inserted into the nozzle is 3-5 mm, and a contact gap between the guide pipe and the nozzle is sealed in a welding mode.

The upper end of the guide pipe extends out of or is 0.5-2.5 mm higher than the upper end surface of the upper sealing element, the guide pipe is inserted into the lower sealing element by 7-8 mm, and the guide pipe is in clearance fit or close contact fit with inner holes of the upper sealing element and the lower sealing element before extrusion.

The outer diameter of the upper sealing element is 6-10 mm, and the thickness of the upper sealing element is 1-3 mm; the outer diameter of an upper end cylinder A of the lower sealing piece is 6-10 mm, and the thickness of the upper end cylinder A is 1-3 mm.

The width and the height of the annular cutting edge are both 0.3-0.6 mm; the diameter of which is specifically optimized according to the dimensions of the other components.

The external diameter of the sleeve is 5-7 mm, the height is 6-8 mm, the size design ensures that the sleeve is in clearance fit or close contact fit with the guide pipe before being extruded, good sealing is formed between the sleeve and the guide pipe after being extruded, and the polarization voltage is applied to the nozzle through the contact pin, the sleeve and the guide pipe.

The materials of the upper pressing body, the lower pressing body, the detector body and the contact pin are metals, and preferably stainless steel materials.

The opening end of the through hole at the lower end of the guide tube is a cone frustum-shaped bell mouth.

The lower surface of the upper pressing body, the upper surface of the lower pressing body and the upper and lower surfaces of the sleeve are respectively provided with a conical annular cutting edge, and the upper pressing body and the lower pressing body are tightly pressed with the detector body through screws; in the pressing process, the four conical annular cutting edges are respectively embedded into the upper surface and the lower surface of the upper sealing element and the lower sealing element to realize embedded sealing; meanwhile, the conical annular cutting edge inwards extrudes the upper sealing piece and the lower sealing piece in the embedding process, so that the inner hole of the conical annular cutting edge is reduced, the guide pipe is extruded, and finally, contact gaps between the inner holes of the hydrogen gas cavity, the air cavity and the upper and lower sealing pieces and the outer diameter of the guide pipe are sealed. According to the invention, the structure of the nozzle assembly is innovatively designed according to mechanical and material principles, and the sleeve can introduce polarization voltage to the nozzle besides the supporting function; the parts are all multifunctional.

In addition, polyimide has elastic deformation and can be used for embedded sealing. Its volume resistance at 300 ℃ is 10¹¹-10¹²Omega/cm, which ensures good electrical insulation of the mu-FID at high temperature; the high-temperature resistant polyimide has a long-term service temperature of more than 300 ℃ and a glass transition temperature of more than 320 ℃, and fully aromatic polyimide (Vespel) produced by DuPont in the United states has no glass transition temperature and cannot be softened under the high-temperature and pressure resistance for a long time.

Compared with the prior art, the nozzle assembly has the following advantages:

1. the upper pressing body, the lower pressing body, the hard metal sleeve and the upper sealing piece and the lower sealing piece are innovatively designed to extrude, the embedded sealing mode of the cutting edge is realized, the sealing structure is multifunctional, an additional two-way and a screwing cap are not needed, and the sealing structure is simpler.

2. The new embedded sealing design of the cutting edge has the advantages that after the cutting edge is embedded, all sealing surfaces are mutually compressed, and compared with the previous taper cutting sleeve type sealing wire ring, the sealing is more reliable under multiple high-temperature and low-temperature cycles.

3. The new nozzle assembly structure provides a smaller dead volume of the combustion chamber and less perturbation of the air flow, which is beneficial to improving the stability of the mu-FID.

4. The sealing element is made of polyimide or Vespel material with elasticity, high temperature resistance, insulation and excellent sealing performance, and the stable insulation and pressure-resistant sealing performance of the mu-FID at the temperature of 300-350 ℃ is ensured.

Drawings

FIG. 1 is a schematic cross-sectional view of a nozzle assembly. In the figure: 1-nozzle, 2-guide tube, 3-upper sealing element, 4-sleeve, 5-lower sealing element, 6-upper pressing body, 7-lower pressing body, 8-detector body, 9-annular cutting edge, 10-contact pin, 11-screw, 12-lower hydrogen gas cavity and 13-upper air cavity.

FIG. 2 is an experimental spectrum of μ -FID developed using the new nozzle assembly of the present design.

FIG. 3 is an experimental spectrum of a prior art μ -FID.

Detailed Description

A nozzle assembly for a miniature hydrogen flame ionization detector, comprising: comprises a nozzle 1, a guide pipe 2, an upper sealing element 3, a sleeve 4, a lower sealing element 5, an upper pressure body 6, a lower pressure body 7 and a detector body 8 which are coaxially arranged; the nozzle 1 and the guide pipe 2 are respectively straight-through circular pipes with two open ends; the upper sealing element 3 and the lower sealing element 5 are cylinders provided with through holes along the axis, the lower sealing element 5 comprises an upper end cylinder A and a lower end cylinder B which are coaxially arranged, the diameter of the lower end cylinder B is smaller than that of the upper end cylinder A, the upper end cylinder A and the lower end cylinder B form a coaxial T-shaped cylinder, the diameters of the through holes formed in the upper parts of the upper sealing element 3, the upper end cylinder A and the lower end cylinder B along the axis are the same, the diameter of the through hole formed in the lower part of the lower end cylinder B along the axis is smaller than that of the through hole formed in the upper part communicated with the lower end cylinder B along the axis, namely, an annular step is formed at the through hole in the lower end cylinder B, and the opening end of;

the detector body 8 is a hollow structure provided with a circular through hole from top to bottom, and the upper end surface and the lower end surface of the detector body are provided with threaded holes; an upper pressure body 6 and a lower pressure body 7 which are provided with through holes coaxial with the circular through hole are respectively arranged at the upper opening end and the lower opening end of the circular through hole of the detector body 8, a circular protrusion coaxial with the through hole is arranged at the periphery of the circular through hole at the lower end of the upper pressure body 6, the lower circular protrusion extends into the circular through hole of the detector body 8 from the upper opening end of the circular through hole of the detector body 8, an upper circular protrusion coaxial with the through hole is arranged at the periphery of the circular through hole at the upper end of the lower pressure body 7, and the upper circular protrusion extends into the circular through hole of the detector body 8 from the lower opening end of;

the tubular lower end of the nozzle 1 is inserted into the upper opening end of the guide tube 2, the nozzle 1 and the guide tube 2 are arranged in the circular through holes of the upper pressing body 6, the lower pressing body 7 and the detector body 8, and the nozzle 1 and the guide tube 2 are coaxially arranged with the circular through hole of the detector body 8; through the through holes on the upper sealing element 3 and the lower sealing element 5, the outer wall surface of the guide tube 2 positioned in the detector body 8 is sequentially sleeved with the upper sealing element 3, the sleeve 4 and the lower sealing element 5 from top to bottom in a penetrating manner, the lower end surface of the guide tube 2 is abutted with the annular step of the through hole in the lower end cylinder B, and the lower end surface of the upper sealing element 3 and the upper end surface of the lower sealing element 5 are respectively abutted with the upper end surface and the lower end surface of the sleeve 4; a through hole is arranged on the side wall surface of the middle part of the detector body 8, and the contact pin 10 penetrates through the through hole to be abutted against the outer wall surface of the sleeve 4;

the lower surface of the upper pressing body 6, the upper surface of the lower pressing body 7 and the upper and lower surfaces of the sleeve 4 are respectively provided with an annular cutting edge 9, and the upper pressing body 6 and the lower pressing body 7 are tightly pressed with the detector body 8 through a threaded hole by a screw 11; in the compressing process, the four annular cutting edges 9 are respectively embedded into the upper surface and the lower surface of the upper sealing element 3 and the lower sealing element 5 to realize embedded sealing; meanwhile, the annular cutting edge 9 inwards extrudes the upper sealing piece 3 and the lower sealing piece 5 in the embedding process, so that the inner hole of the upper sealing piece is reduced, the guide pipe 2 is extruded, and extrusion sealing is realized; finally sealing a hydrogen cavity 12 at the lower circular through hole of the lower pressing body 7, an air cavity 13 at the upper circular through hole of the upper pressing body 6 and contact gaps between the inner through holes of the upper and lower sealing elements and the outer wall of the guide pipe 2.

The material of the nozzle 1, the guide pipe 2 and the sleeve 4 is metal; the materials of the upper sealing part 3 and the lower sealing part 5 are polyimide, Vespel or other high polymer materials which are high temperature resistant and have the insulation resistance of more than 1010 ohms.

The inner diameter of the nozzle 1 is 0.05-0.3 mm, and the outer diameter is 0.3-0.79 mm; the inner diameter of the guide pipe 2 is 0.4-0.8 mm, the outer diameter is 0.8-2.0 mm, the length is 15-35 mm, the length of the nozzle 1 inserted into the guide pipe 2 is 3-5 mm, and the contact gap between the nozzle and the guide pipe is sealed in a welding mode.

The upper end of the guide pipe 2 extends out of or is 0.5-2.5 mm higher than the upper end surface of the upper sealing element 3, the guide pipe 2 is inserted into the lower sealing element 5 for 7-8 mm, and the guide pipe is in clearance fit or close contact fit with inner holes of the upper sealing element 3 and the lower sealing element 5 before extrusion.

The outer diameter of the upper sealing piece 3 is 6-10 mm, and the thickness is 1-3 mm; the outer diameter of an upper end cylinder A of the lower sealing piece 5 is 6-10 mm, and the thickness of the upper end cylinder A is 1-3 mm.

The width and the height of the annular cutting edge 9 are both 0.3-0.6 mm; the diameter of which is specifically optimized according to the dimensions of the other components.

The external diameter of sleeve 4 is 5 ~ 7mm, and height 6 ~ 8mm, and size design guarantees that it is clearance fit or closely pastes the cooperation of connecing with the inlet tube 2 before the extrusion, forms good sealedly with inlet tube 2 after the extrusion, and polarization voltage passes through contact pin 10, sleeve 4 and inlet tube 2 and adds to nozzle 1.

The materials of the upper press body 6, the lower press body 7, the detector body 8 and the contact pin 10 are metals, preferably stainless steel materials.

The opening end of the through hole at the lower end of the guide tube 2 is a cone frustum-shaped bell mouth.