SE459889B - SENSOR ELEMENTS IN AN EXTENSION SENSOR BY HALOGENS LECTURER - Google Patents

Description

459 889 2 10 15 20 25 30 35 Said sensitive elements of surface ionization transducers also operate at temperatures of 900-1200 ° C, and after a certain time its anode structure is destroyed, the sensitive element itself is "poisoned", its sensitivity is lost, and to restore it requires heat treatment of the sensitive element at higher temperatures (1200-14oo ° c; and longer time. A11: this results in the life of the sensitive element being shortened.

Here and below, the term "poisoning" means a sharp increase in the emission background current of positive ions from the surface of the platinum anode in the absence of halogen-containing compounds within the space between the anode and the cathode, and at the same time such a decrease in the ionization sensor's sensitivity to halogen-containing compounds. to detect these compounds at their origin between the anode and the cathode. To eliminate "poisoning" of the sensitive elements of the sensor, it is necessary to allow an oxygen-containing gas, purified from halogen-containing compounds, to pass through the sensor under high temperatures (1200-1400 ° C) and for a longer time (a few hours or even 24 hours). .

BACKGROUND OF THE INVENTION The main object of the present invention is to provide a sensitive element of surface ionization sensors with halogen leak detectors, the anode and cathode of which are designed to allow an extension of the life and stability of the element by reducing its "poisoning".

This object is achieved - in a sensor element in a surface ionization sensor in halogen leak detectors, comprising coaxially arranged a platinum spiral anode, intended to be fed with an energy source, and a cathode - according to the invention in that the platinum spiral anode is made in the form of two series-connected parts, the first part of the anode is intended to be placed at the input opening of the sensor and the cathode is located at the second part of the spiral anode, the spiral anode being arranged to assume a higher temperature in operation at the first part than at the second part.

It is expedient for the sensor element to comprise a thermal insulator located at a connection point between the parts of the spiral anode.

The first part of the spiral anode suitably has less spiral thread pitch than the second part of the spiral anode.

It is desirable to design the sensor element so that the first part of the spiral anode has a smaller spiral diameter than the second part of the spiral anode.

Such a constructive design of a sensor element in a surface ionization sensor for halogen leak detectors enables improved stability and reproduction of indications and reduced "poisoning" and extends the service life of the sensor element.

Brief description of the drawing figures The invention is described in more detail below with reference to concrete examples of its embodiment and the accompanying drawings, in which: Fig. 1 shows an overall view of a sensitive element of surface ionization sensor in halogen leak detectors, according to the invention (with recesses); Fig. 2 shows an overall view of another variant of a sensitive element, according to the invention (with recesses); Fig. 3 shows a schematic diagram for connecting sensitive element 1 Fig. 1 to energy source.

Preferred Embodiments of the Invention A sensitive element of surface ionization sensor of halogen leak detectors, according to the invention, comprises coaxially arranged a platinum spiral anode 1 (Fig. 1) and a cylindrical cathode 2. The spiral anode according to this embodiment of the sensitive element is arranged inside the cylindrical cathode 2.

The anode 1 is designed in the form of two series-connected parts 3 and 4 with different temperature conditions. Part 3 of the spiral anode has a higher temperature while its part 4 has a lower temperature. Part 3 of the spiral anode 1 is arranged inside the surface ionization sensor at an input hole 5 of the sensor body 6. The cathode 2 is arranged next to part 4 of the anode. Neither the sensor nor the halogen leak detector are described in this case, since they do not constitute the purpose of the finding. For this purpose, constructions of any sensor and halogen leak detector, which are known to specialists in this field of technology, can be used.

The part 3 of the spiral anode 1 is made with a smaller spiral pitch h1 than the part 4 of the spiral anode 1, i.e. 'h1 <hz, where hz is the spiral pitch of the part 4 of the anode 1.

The sensitive element comprises a heat insulator 7 arranged at the connection point between the parts 3 and 4 of the anode 1 with different temperatures. In the described embodiment, the heat insulator 7 is made in the form of a ceramic plate.

The sensitive element according to the above-described embodiment can be most expediently used when it is necessary to change the temperature of the anode 1 part 3, which can be easily changed by changing the spiral thread pitch h1 of the spiral anode 1 part 3. ' A sensitive element according to the invention represented in Fig. 2 and made analogous to the sensitive element in Fig. 1, is characterized in that a rod cathode 8 (Fig. Z1 is arranged inside a platinum anode 1. A part 9 of the spiral anode 1, which has a higher temperature, is made with a smaller diameter d1 for the spiral than the part 10 of the spiral anode 1 with a lower temperature, i.e. d1 <d2, when d2 is the diameter of the spiral within section 10.

The spiral anode 1 is wound on a holder 11 made of a porous dielectric, for example aN'J alumina in such a way that its part 9 is arranged at an input hole 12 in the sensor body 13 and the cathode 8 is mounted in this holder 11 along the part of the anode 1 10. The thermal insulator 7 in the sensitive element in the described embodiment is made of a ceramic coating 14.

This variant of the sensitive element can best be used in cases where the surface ionization sensor in a halogen leak detector works during work processes with vibration and impact stresses.

In Figures 1, 2, the numbers 15, 16, 17, 17, 18, 19, 20 and the connections of the cathodes 2, 8 and the anode 1.

Fig. 3 shows a schematic diagram for coupling the sensitive element according to the invention (Fig. 1) to energy sources 21 and 22.

The outputs 17 and 18 of the anode 1 are connected to the energy source 21, and the output 15 of the cathode 2 is connected to the energy source 22 via a microampering meter 23.

No diagram for connecting the sensitive element according to Fig. 2 is shown, since it is analogous to the diagram in Fig. 3.

The sensitive element in the surface ionization sensor for halogen leak detectors according to the invention consists in the following: The analyzed gas, which comprises halogen-containing compounds, for example freon, penetrates into the body 6 (Fig. 1) in the surface ionization sensor of the halogen leak detector via the inlet hole 5. along the arrow A. The spiral anode 1 is heated by means of the energy source 21 (Fig. 3), for part 3 up to temperatures of 1000-1400 ° C and for part 4 to temperatures of 500-700 ° C. The energy source 22 generates a potential difference between the anode 1 and the cathode 2 of 100-300 V.

As the analyzed gas flows through part 3 (Fig. 1), which is heated 1000 to 1000-1400 ° C, the halogen-organic compounds in carbon dioxide, water and halogens decompose. As the gas continues to flow through the space between the cathode 2 and the part 4 of the anode 1, halogens cause a change in the emission current of positive ions from the surface of the part 4. Changes in the emission current 10 15 20 25 459 889 are detected by means of the microamperemeter 23 (Fig. 3).

At the connection point between the parts 3 of the anode 1 (Fig. 1) and 4 is the thermal insulator 7, which does not allow the emission current to flow between the part 3 of the anode 1 and the cathode 2.

The working principle of the sensitive element in the surface ionization sensor of the halogen leak detector according to Fig. 2 is analogous to the working principle of the sensitive element according to Fig. 1.

Since the cathode 2 (Fig. 1) as well as the cathode 8 (Fig. 2) are located at the part 4 and With lower temperature, surface ionization occurs just along this part, which ionization at temperatures of 500-700 ° C practically does not change the surface of this part of the spiral anode 1, which increases the indication stability of the sensitive element, reduces its "poisoning" and increases its service life. By the preheating treatment at the spiral anode 14øo ° c, gannic part 3 resp. 9, which has a higher temperature, up to 1000- a more complete decomposition of halogen substances is achieved, which in turn ensures the halogen leak detector more efficient reproduction of indications, when it is provided with the proposed sensitive element in the surface ionization sensor.

Industrial application The sensitive element in the surface ionization sensor of a halogen leak detector according to the invention can be used in vacuum and cooling technology for the detection of leaks in vacuum and gas-filled systems.

Claims (4)

1. A 01 WD O) CO ¶> Claims 1. Sensor elements in a surface ionization sensor for halogen leak detectors. comprising coaxially arranged a platinum spiral anode (1) / intended to be supplied with an energy source (ZIL and a cathode (2, 8), characterized in that the platinum spiral anode (1) is designed in the form of two series-connected parts (3. 4. 9 The first part (3, 9) of the helical anode (1) is intended to be placed at the entrance opening (5, 12) of the sensor and the cathode (2, 8) is located at the second part (4) of the helical anode (1). ), wherein the spiral anode is arranged to assume a higher temperature in operation at the first part than at the second part. Sensor element according to claim 1, characterized in that it comprises a thermal insulator (7) located at a connection point between the parts (3, 4) of the spiral anode (1). Sensor element according to Claim 1 or 2, characterized in that the first part (3) of the spiral anode (1) has a smaller spiral thread pitch (hl) than the second part (4) of the spiral anode (1). Sensor element according to Claim 1 or 2, characterized in that the first part (9) of the spiral anode (1) has a smaller spiral diameter (dl) than the second part (10) of the spiral anode (1).