CH683880A5 - Photocell, in particular for detecting UV radiation. - Google Patents

Description

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description

The invention relates to a photocell according to the preamble of claim 1, as is known from CH-PS 425 014.

Such a photocell forms a photoelectronic component, generally an electron tube, in which the generation of charge carriers is significantly influenced by electrons, so-called photoelectrons, which are liberated from the photocathode by irradiation.

Assuming some idealizing assumptions, the photoelectrons generated at the cathode are proportional to the radiation power of monochromatic radiation impinging on the cathode, and also to the effective area of the photocathode, in which case a constant radiation power is assumed. A distinction is made between vacuum photocells and gas photocells. In both types, the photoelectrons are accelerated from the cathode to the anode by a field between the anode and cathode. It goes without saying that the electrode system of such a photocell composed of cathode and anode must consist of electrically conductive material.

In vacuum photocells, the charge carrier current is identical to the photoelectron current. The photoelectrons are absorbed at the anode.

In gas photo cells, the photoelectrons ionize the gas present and generate positive and negative charge carriers. The charge carrier current is composed of the negative charge carriers accelerated towards the anode and the positive charge carriers accelerated towards the cathode.

In gas photo cells, such as those used in UV detectors for flame monitoring, the charge carriers generated by the photoelectrons initiate processes that lead to an independent discharge. This is characterized in that the charge carrier current is now independent of the photoelectrons and thus of the radiation generating these photoelectrons. In this application, the number of photoelectrons provided on the cathode determines the time after which, after application of a voltage which creates the electrical field between the anode and cathode, the photocell changes from the de-energized to the current-carrying and independent discharge state.

In any case, the charge carrier current produced signals the presence of radiation, in particular ultraviolet radiation (UV radiation).

Due to the technical development in the field of UV detectors for flame monitoring, the photocells used in such detectors are subject to ever higher demands with regard to their UV sensitivity. On the other hand, since the manufacturers of such detectors naturally endeavor to limit the variety of types of the photocells they use and to keep the economic outlay for new, more sensitive photocells as low as possible, further improvements are difficult to achieve.

A preferred way of increasing the sensitivity of a UV photocell is to increase the probability of an electron being released from the cathode, which can be achieved by increasing the cathode area. For this reason, so-called plate electrodes have been used for a long time, which are punched out of sheet metal. As has been found, the greater outlay for a plate electrode can be limited to the cathode, as is evident from the applicant's DE-PS 3 715 924. In the former case, the surface of the plate cathode has an angle of inclination of 45 ° with respect to the longitudinal axis of the photocell.

As far as the buyers and manufacturers of the UV detectors are concerned, they also wish to keep the contact pin assignment with regard to the connections of the cathode and the anode and to keep the technically used area of the spatial distribution of the radiation sensitivity of the photocell they are using essentially unchanged , because they do not want to change their detectors in which the new photocells are to be used.

On the manufacturer's side, any necessary cost increases should be economically justifiable.

The object on which the invention is based is therefore seen in creating a photocell of the type mentioned in the preamble of claim 1, which has a greater sensitivity to ultraviolet radiation with the same assignment of the contact pins and without a significant change in the spatial distribution characteristic of the radiation sensitivity, and with little technical effort.

This object is achieved according to the invention in the case of a photocell with two wire electrodes, the effective regions of which consist of sections of the two wires which run essentially parallel to one another, with the features of the characterizing part of claim 1.

It goes without saying that the side exposed to the radiation is decisive; however, the pressure between two flat, plane-parallel stamps is preferred, since it is the simplest, and results in plane-parallel surfaces in the region of the resulting widening and corresponding thinning by pressing the section of the electrode wire that represents the effective electrode.

This reshaping of the effective electrode that is used as the cathode results in a greater sensitivity to radiation, in particular UV radiation, solely due to the increased surface area. Since the deformation only affects the electrode, it is not necessary to change the assignment of the associated contact pins of the photocell. Furthermore, the pressing process required according to the invention is very simple in terms of production technology and is inexpensive.

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The size of the area achieved by the deformation is determined on the one hand by the desired stability of the electrode system and on the other hand by the undesirable deviation from the original sensitivity distribution. A cathode area of 7 mm 2 (with a width of 1 mm and a length of 7 mm) has proven to be suitable.

The cathode surface created by plane pressure must be rotated at an angle to the common plane of the two sections so that on the one hand the characteristic of the radiation sensitivity remains largely unchanged, on the other hand the distortion of the electrical field existing between the anode and cathode is as low as possible.

The least distortion of the electric field is given when the cathode surface is perpendicular to the plane that the electrode sections have in common. However, such a position changes the characteristic of the radiation sensitivity significantly. Taking both requirements into account, the surface created by the plane pressing is inclined at an angle of approximately 45 ° to the common plane of the two sections, in contrast to the prior art according to DE-PS 3 715 924, in which, as stated, only one inclination relative to the longitudinal axis of the photocell. The considerations corresponding to the invention also apply to two electrode surfaces arranged opposite one another.

An embodiment of the photocell according to the invention with a face-pressed cathode and a conventional wire anode naturally lends itself to direct current operation. For operation with alternating current, on the other hand, in which the two electrodes alternately serve as anode and cathode, it is advantageous to press the two sections of the wires that form the effective electrodes and to arrange the surfaces that face each other in such a way that they form an angle between them Include ß of about 90 °. In this case, radiation incidence in the direction of the bisector is of course the most favorable, in which radiation incidence is guaranteed at 45 ° to the surfaces of both effective electrodes.

The invention and its advantageous embodiments are explained in more detail below with reference to the embodiments shown in the drawing in comparison with the prior art.

Show

I A to 1 C schematic diagrams of various wire electrode shapes according to the prior art in an oblique view:

II shows a spatial sensitivity distribution of the photocell according to FIGS. 1A and 3, III in DC operation;

III shows a side view of a photocell using the electrode system according to FIG. 1A;

IV shows the spatial sensitivity distribution of a photocell according to FIGS. V A to V C;

V A to V C a first embodiment of the invention for direct current operation in front view, side view and top view with an electrode arrangement inclined to the longitudinal axis B:

Fig. VI A to Fig. VI C an embodiment corresponding to Fig. V A to Fig. C for AC operation;

VII A to VII C a second embodiment of the photocell for direct current operation in front view, side view and top view with an electrode arrangement parallel to the longitudinal axis B;

Fig. Vili A to Fig. Vili C a Fig. VII A to Fig. VII C corresponding embodiment of the photocell for AC operation;

IX A to IX C a third embodiment of the photocell for direct current operation again in front view, side view and top view with the electrode arrangement perpendicular to the longitudinal axis B;

Fig. X A to Fig. X C a Fig. IX A to Fig. IX C corresponding embodiment of the photocell for AC operation.

The electrode systems shown schematically in FIGS. 1A, 1B and IC each consist of four lead wires, namely 1, 2, 3 and 4, with wires 1 and 2 on the one hand and 3 and 4 on the other hand a wire electrode 6 and 5 or 6a and 5a or 6b and 5b are assigned. These are essentially perspective sketches. The sheath surrounding these electrode systems has been omitted from these figures for the sake of clarity. Otherwise, the same parts are always provided with the same reference numerals in the following.

The three prior art embodiments according to FIGS. 1A to 1C differ from one another with regard to the arrangement of the effective electrodes or the sections 7, 8 or 7a, 8a or 7b, 8b arranged essentially parallel to one another. Only these essentially parallel sections of the electrodes are effective or “effective” and determine the function and sensitivity of the photocell.

III shows a schematic representation of an actual embodiment of a photocell 11 according to FIG. 1A in side view, only two of the four extending downwards through the bottom 13 of the envelope 14 of this photocell 11, which is permeable to radiation, in particular UV radiation Contact pins 3 and 4 are visible, which cover two further contact pins (1 and 2), just as the electrode 5 also covers the electrode 6 here. III thus shows a side view in the direction of arrow A in FIG. 1A.

Since this photocell is operated with DC voltage according to FIGS. 1A and III, and thus the same electrode is always used as the cathode, the spatial sensitivity distribution is asymmetrical. II shows such a sensitivity distribution. The cathode of the pair of electrodes shown in plan view in FIG. II is identified by the letter K, the anode by the letter A.

V A, V B and V C now show a first embodiment of the photocell according to the invention.

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dung, which corresponds in structure to that of the known photocell according to FIGS. I A and III. This is particularly clear from a comparison of Fig. III with Fig. V B.

The difference according to the invention now consists in the fact that in this embodiment intended for direct current, one of the two sections 9, 9 'of the wire electrodes, namely section 9 of the wire electrode 5c, has on its side exposed to the radiation a surface 10 which is pressed against the wire and widened. This wire electrode 5c is thus the cathode, with a widened cathode surface (surface 10), whereas the electrode 6c serves as an anode in the usual form. The designations 13 for the base and 14 for the casing (for example made of quartz glass) have been omitted for the sake of clarity, especially since they would be repeated in all the embodiments. It goes without saying that the respective contact pins 1 to 4 are melted into the respective bases 13 (FIG. III). The reference numeral 12 designates the respective pump stem through which the pump is evacuated or filled with gas.

It is understood that in FIG. V B the electrode 5c with the surface 10 as the cathode lies in front of the electrode 6c as the anode, and hides it for reasons of symmetry.

The structure of the photocell according to FIGS. VI A, VI B and VI C corresponds essentially to that of the photocell according to FIGS. VA, VB and VC, those figures show the design for alternating current, which is why both the wire electrode 5c 'and the Wire electrode 6c 'have a widened surface 10 or 10' which is obtained by pressing. VI B shows the rear side of the section 10 of the electrode 5c 'widened by pressing. It goes without saying that this embodiment must be intended for alternating current, since the anode and cathode alternate here, which is why the broadening of the cathode area can only be ensured by the fact that both effective electrodes are given widened sections 10 and 10 'by pressing.

The embodiment according to FIGS. VII A, VII B and VII C is again intended for direct current, while the embodiment corresponding to the structure according to FIGS. Vili A, Vili B and VIII C is again intended for alternating current. Since the arrangement in these two embodiments was based on the prior art according to FIG. 1B, the preferred arrangement of the cathode surfaces from FIGS. VII C and FIG. Vili C can be seen particularly clearly, since the effective electrodes or sections 7a, 8a, here are arranged parallel to the plane of the drawing. According to the invention, there are also extruded sections 10 and 10 'which develop the advantageous effects explained at the outset. In the case of the embodiment according to FIGS. Vili A, Vili B and VIII C for alternating current, FIG. Vili C shows the preferred arrangement of the two plane-pressed sections 10 and 10 'in the case of one for

Alternating current suitable photocell 11, namely insofar as the surfaces facing each other form an angle β of approximately 90 ° between them. It goes without saying that this 90 ° arrangement also applies to the AC version according to FIGS. VI A, VI B and VI C, even if this is not visible there with regard to the inclined arrangement of the electrodes with respect to the plane of the drawing.

The configurations according to FIGS. IX A, IX B and IX C for direct current on the one hand and FIGS. XA, XB and XC for alternating current on the other hand correspond to the known arrangement according to FIG. IC, the arrangement of area 10 below being shown in FIG. IX B. the angle (see also FIG. VII C) equal to 45 ° and from FIG. XB the arrangement of the two surfaces 10 and 10 'at the angle β is equal to 90 °.

The configurations according to the invention are oriented in the arrangement in space according to the main directions of incidence C, D and E of the radiation shown in FIGS. 1A, IB and IC, these main directions of incidence each perpendicular to the plane of the two effective electrodes or sections 7, 8 and 7a, 8a and 7b, 8b run. The relationship shown above then applies to the alignment of the face-pressed electrodes.

The arrangement of the face-pressed electrodes further ensures that the cathode is not shadowed by the anode in the main directions of incidence.

IV shows a sensitivity diagram corresponding to FIG. II for the embodiment according to the invention according to FIGS. VA, VB and V C. How a comparison of the spatial sensitivity distribution shown in FIG. II with that shown in FIG. IV shows achieved a significantly higher sensitivity by the invention, and this while maintaining the characteristic.

If reference was made to the respective main directions of incidence of the radiation according to arrows C, D and E with regard to FIGS. 1A, 1B and IC, this naturally does not change the fact that the actually incident radiation can deviate from this by up to 45 °, as explained above. This is for example in Fig. III, see arrow F, which shows a possible direction of incidence for the embodiment according to the prior art according to Fig. I A and also the embodiment according to the invention according to Fig. V A, V B and V C according to Fig. IV.

Claims (2)

Claims 1. photocell (11), in particular for detecting UV radiation with two wire electrodes (5c, 6c; 5c ', 6c), the effective areas of which consist of two sections (9, 9') of the two wires which run essentially parallel to one another, characterized in that at least one of the two sections (9, 9 ') has, at least on its side exposed to the radiation, a surface (10, 10') pressed flat while the wire is being widened, and that this surface (10, 10 ') is at an angle a of about 45 ° to the common 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th 7 C H 683 880 A5 Level of the two sections (9, 9 ') is arranged inclined. 2. Photocell according to claim 1, characterized in that both sections (9, 9 ') are face-pressed on both sides and the resulting, mutually facing surfaces (10, 10') form an angle β of approximately 90 ° between them. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5