JPH054006U - Gas chromatograph detector nozzle application structure - Google Patents

Abstract

(57) [Summary] [Purpose] To facilitate the maintenance of nozzles in a gas chromatograph detector that employs a nozzle application method. [Arrangement] A nozzle 14 capable of generating a flame and a collector 23 capable of detecting a signal current are arranged inside the mounting body 1 so as to face each other. The nozzle 14 is insulated from the mounting body 1 and a high voltage is applied to form a high electric field between the nozzle 14 and the collector 23. An insulating block 10 having a conductive portion 12 and an insulating portion 11 inside and outside is arranged inside the mounting body 1, and the conductive portion 12 inside the block 10 is insulated from the mounting body 1 via an external insulating portion 11. To do. The high-voltage power supply terminal 16 is connected to the conductive part 12, and the nozzle 14 is detachably attached to the conductive part 12 separately from the high-voltage power supply terminal 16.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a nozzle application structure of a gas chromatograph detector which employs a nozzle application method and which enables easy maintenance of nozzles.

[0002]

[Prior Art]

 For example, FID (hydrogen flame ionization detector), which is often used as a gas chromatograph detector, includes a nozzle that generates a hydrogen flame and a collector that detects the ion current of the sample ionized by the hydrogen flame. A high voltage is applied to one of them to form a high electric field electron trapping region between the nozzle and the collector.

The detector is divided into a nozzle applying method for applying a high voltage to a nozzle and a collector applying method for applying a collector as described in Japanese Utility Model Laid-Open No. 1-163863, according to a high voltage applying method. In the former case, for example, as shown in FIGS. 3 and 4, the lower portion of the mounting body a is embedded inside the heat insulating material b, and the nozzle body c and the nozzle tube e integral with the nozzle d are provided inside the body a. Was integrally attached, and the high-voltage power supply terminal f was attached to the nozzle d.

[0004]

[Problems to be solved by the device]

 In this conventional nozzle application structure, for example, when the liquid phase of the column adheres to the nozzle and is to be cleaned or replaced, the cap g is removed, the collector i is pulled up together with the signal cable h, and then the power is supplied. It was necessary to remove the terminal f, loosen the nozzle body c, and remove the nozzle d together with the nozzle tube e. However, when removing the power supply terminal f, it is necessary to take out the power supply cable j from the heat insulating material b, and there is a problem that this work of taking out is very complicated and troublesome.

The present invention solves such a problem, and in a detector for a gas chromatograph adopting a nozzle application method, the nozzle and the high-voltage power supply terminal are separately configured so that the nozzle can be easily removed. It is an object of the present invention to provide a nozzle application structure for a detector for a gas chromatograph that can be easily maintained.

[0006]

[Means for Solving the Problems]

 Therefore, in the nozzle applying structure of the gas chromatograph detector of the present invention, the nozzle capable of generating a flame and the collector capable of detecting a signal current are arranged facing each other inside the mounting body, and the nozzle is mounted on the mounting body. In the nozzle application structure of the gas chromatograph detector that insulates from the above and applies a high voltage to form a high electric field between the nozzle and the collector, the inside and outside of the mounting body are composed of a conductive part and an insulating part. The insulating block is installed to insulate the conductive part inside the block from the mounting body through the external insulating part, connect the high-voltage power supply terminal to the conductive part, and separate the high-voltage power supply terminal from the conductive part. The feature is that the nozzle can be detached easily by detaching it, and the nozzle can be easily maintained.

[0007]

【Example】

 Hereinafter, the illustrated embodiment in which the present invention is applied to an FID will be described. In FIG. 1 and FIG. 2, reference numeral 1 denotes a hollow cylindrical mounting body attached to a detector housing 3 via a holding plate 2. A heater block 4 is mounted on the lower peripheral surface, and is fixed via a support plate 5 and a nut 6.

An air-fuel mixture chamber 8 communicating with the combustion chamber 7 is provided in the lower inner portion of the mounting body 1, a delivery end of a column (not shown) is connected to the chamber 8, and a hydrogen conduit 9 is provided immediately above it. It is open.

An insulating block 10 is fixed to the bottom of the combustion chamber 7, and the block 10 has an inner-outer double structure, and the outside is divided by an insulating portion 11 made of an insulating member such as ceramics. A conductive portion 12 made of a conductive material such as stainless steel is fixed inside.

A concave hole 13 is formed on the upper surface of the conductive portion 12, and a nozzle 14 made of a conductive member is attached to the hole directly below the hole 13 by appropriate means. In this case, in the embodiment, as a mounting means of the nozzle 14, a screw portion 14a is provided on the lower peripheral surface of the nozzle 14 and is screwed into the screw portion 15 formed immediately below the recessed hole 13, and the nozzle 14 is substantially It is formed in a hexagonal column shape.

A high-voltage power supply terminal 16 is laterally connected to the inside of the conductive portion 12 by an appropriate means, and the inside of the insulating portion 11 serving as a wiring area of the terminal 16, the mounting body 1, and the heater block 4 is provided. Therefore, the insulating tube 17 made of an insulating member such as ceramics is provided.

An air conduit 18 is opened in the upper part of the combustion chamber 7, and an insulating ring 20 made of an insulating member such as ceramics is accommodated in the bottom of a collector holding chamber 19 formed above the chamber 7, A conductive ring 21 made of a conductive material is housed in the locking step portion 20 a of the ring 20.

A signal pin 22, which is electrically connected to an electrometer amplifier (not shown), is detachably connected to the inside of the conductive ring 21, and a conductive member is attached to the upper surface of the conductive ring 21 via an overhanging piece 23a. The collector 23 is locked, and the insulating ring 24 made of an insulating member such as ceramics is housed on the projecting piece 23a.

A cap 27 is accommodated on the upper surface of the insulating ring 24 via spacers 25 and 26, and the cap 27 is fixed via a connecting ring 29 screwed into a screw portion 28 of the mounting body 1.

[0015]

[Action]

 In manufacturing the insulating block 10, the nozzle applying structure of the gas chromatograph detector configured as described above first processes the insulating portion 11 and the conductive portion 12 into a predetermined shape with a predetermined insulating member or a conductive member. Next, as these fixing means, for example, a predetermined metal layer is formed on the inner and outer surfaces of the insulating portion 11, and then these metal layers are plated with nickel, for example, and the insulating portion is welded through the insulating portion. The insulation block 10 is manufactured by integrally fixing 11 and the conductive portion 12 housed therein.

On the other hand, the outer surface of the conductive part 12 and the fixed position of the bottom part of the combustion chamber 7 are plated with nickel, and the insulation part 11 housed inside the bottom part and the insulation part 11 are insulated from each other through a welding action such as brazing. The conductive portion 12 housed inside the edge portion 11 is integrally fixed, and the insulating block 10 is fixedly mounted inside the mounting body 1.

On the other hand, screw holes and through holes are formed at corresponding positions of the conductive portion 12 and the insulating portion 11, and the through holes are also provided at corresponding positions of the mounting body 1 and the heater block 4 facing the through holes. After forming the through hole having the same diameter as that of the insulating block 10 and assembling the insulating block 10, the power supply terminal 16 is inserted into the through hole and the through hole through the insulating tube 17, and the end portion of the terminal 16 is inserted into the nozzle holder 12. Connect by screwing in.

After the insulating block 10 is assembled, the nozzle 14 is screwed into the threaded portion 15 of the conductive portion 12, the insulating ring 20 is housed in the bottom of the collector holding chamber 19, and the engaging portion 20a of the ring 20 is electrically conductive. The ring 21 is accommodated.

Then, the signal pin 22 is attached to the conductive ring 21, the collector 23 is hooked on the upper surface of the ring 21 via the protruding piece 23a, and the insulating ring 24 is accommodated on the protruding piece 23a. Then, the spacers 25 and 26 are superposed on the ring 24. After that, the leg portion of the cap 27 is accommodated on the spacer 26, and this is fixed by the connecting ring 29 screwed into the screw portion 28 of the mounting body 1.

In the nozzle application structure thus assembled, air is supplied from the air conduit 18 into the combustion chamber 7 during detection operation, and the carrier gas and the reagent flow out from the column into the mixture chamber 8 and the hydrogen conduit 9 is supplied. Hydrogen flows out of the nozzle, and the air-fuel mixture moves upward and is ejected from the nozzle 14 to generate a hydrogen flame around the nozzle.

At the time of such a detection operation, a high negative voltage is applied to the power supply terminal 16 and the collector 23 is placed at a positive potential. That is, the negative voltage is supplied to the conductive portion 12 connected to the terminal 16 via the power supply terminal 16 and applied to the nozzle 14 attached to the conductive portion 12. In this case, the conductive portion 12 and the nozzle 14 are insulated from the mounting body 1 via the insulating wall 11 of the insulating block 10, and the power supply terminal 16 is insulated from the mounting body 1 and the heater block 4 via the insulating tube 17. It

The collector 23 is electrically connected to the conductive ring 21 and the signal pin 22 via the overhanging piece 23 a, and inputs the detected ion current to the electrometer amplifier, while the collector body 23 is attached via the insulating rings 20 and 24. Insulated from 1.

With such a detection operation, the liquid phase of the column and the soot at the time of combustion of the sample adhere to the nozzle 14, and noise is mixed by such combustion and the like, and the accuracy of analysis gradually decreases. It is necessary to clean 14 in a timely manner.

When cleaning the nozzle 14, it is necessary to take it out from the mounting body 1, and the procedure in that case is shown in FIG. That is, when the coupling ring 29 is loosened and removed from the mounting body 1, the following components are merely in a superposed relationship, and therefore the cap 27, the spacer 26, the spacer 25, the insulating ring 24, the collector 23, and the signal pin 22 are removed. The conductive ring 21 and the insulating ring 20 can be easily taken out from above the mounting body 1 in this order.

When these parts are taken out in this manner, the inside of the mounting body 1 is opened above the collector holding chamber 19 and the combustion chamber 7 except for the nozzle 14. Therefore, for example, an appropriate tool such as a box wrench is prepared, and this is inserted into the combustion chamber 7 from above the mounting body 1 and fitted into the nozzle 14, and the nozzle 14 is rotated to loosen the nozzle 14. Next, for example, an appropriate tool such as tweezers may be prepared, and the nozzle 14 may be sandwiched between the tools and taken out from the mounting body 1.

As described above, in the present invention, the nozzle 14 and the power supply terminal 16 for applying the nozzle are separately configured, and when the nozzle 14 is removed, the power supply terminal 16 is not required to be removed, and predetermined parts are removed in order. Therefore, this kind of work can be performed easily and quickly, and the maintenance of the nozzle 14 becomes convenient.

On the other hand, when the nozzle 14 is cleaned and then assembled, the nozzle 14 is screwed into the screw portion 15 and tightened with an appropriate tool such as a box wrench, and the parts such as the insulating ring 20 are reversed from the above. Then, the connecting ring 29 may be screwed into the threaded portion 28.

The present invention is not limited to the FID, but a nozzle for generating a flame and a collector for detecting a signal current are arranged to face each other, and another detector of a type for applying a voltage to the nozzle, for example, a TID. (Thermionic detector) can also be applied.

[0029]

[Effect of the device]

 As described above, the nozzle applying structure of the detector for a gas chromatograph of the present invention has an insulating block having a conductive part and an insulating part inside and outside the mounting body, and the conductive part inside the block is external. It is insulated from the mounting body through the insulation part of the, and the high-voltage power supply terminal is connected to the conductive part, and the nozzle is detachably attached to the conductive part separately from the high-voltage power supply terminal. The nozzle can be removed easily and quickly compared to the case where the power supply terminal is directly attached, which is convenient for maintenance such as cleaning the nozzle.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of the present invention.

FIG. 2 is an exploded cross-sectional view of the main part of the present invention, showing the order of removing the nozzles.

FIG. 3 is a cross-sectional view showing a conventional example.

FIG. 4 is a cross-sectional view showing an enlarged main part of the conventional example.

[Explanation of symbols]

 1 Mounting Body 10 Insulation Block 11 Insulation Part 12 Conductive Part 14 Nozzle 16 High Voltage Power Terminal 23 Collector

Claims (1)

[Claims for utility model registration] [Claim 1] A nozzle capable of generating a flame and a collector capable of detecting a signal current are disposed inside a mounting body so as to face each other, and the nozzle is insulated from the mounting body to achieve a high voltage. In the nozzle application structure of the gas chromatograph detector that applies a voltage to form a high electric field between the nozzle and the collector, an insulating block composed of a conductive part and an insulating part is arranged inside and outside the mounting body. , The conductive part inside the block is insulated from the mounting body via the external insulating part, the high voltage power supply terminal is connected to the conductive part, and the nozzle is detachably attached to the conductive part separately from the high voltage power supply terminal. A structure for applying a nozzle to a detector for a gas chromatograph, which is characterized in that