DE1187748B - Photocell arrangement - Google Patents

Description

Photocell Arrangement The invention relates to a photocell arrangement with at least two photocells connected in series, one of which is a cell is particularly sensitive to radiation of a certain frequency range, while a second cell is particularly responsive to radiation of a different frequency range.

Such a photoelectric cell arrangement with two barrier photocells different spectral sensitivity is already known and can be used for actuation electrical switching operations can be used by different colored light. Included the cells are switched in such a way that the photo effects of the two cells when illuminated are opposite from the same side and act in such a way that such an arrangement only responds to light of certain colors, but not to composite light.

Such a photocell arrangement does not speak to white light on, but can also with single-colored or nearly single-colored light, i. H. at Light within a relatively narrow frequency band, not that light after to distinguish its origin. Therefore, such a cell arrangement is for example useless for the detection of a flame.

It is the aim of the invention to provide a photocell arrangement, the flawless between the ultrared source emitted by a fire and one can distinguish the ultrared source emitted by another source. All so far known devices for the detection of ultrared radiation require an extremely critical setting to choose between an unwanted ultrared source such as a Flame, and a harmless source containing an ultra-red component such as daytime or artificial light. An unwanted false positive can also already be then be brought about when part of a photocell array is in the shade while the other part is exposed to direct radiation.

The photocell arrangement according to the invention has those described Disadvantages does not arise and is characterized by the fact that the excitation of the second Cell by additional irradiation in the frequency range in which the first cell is particularly responds, decreases.

In an expedient further embodiment of the invention, there is Photocell arrangement from a first, from a photoresistor made of polycrystalline Cadmium sulfide, lead sulfide or cadmium selinide formed cell, while the second Cell can be a photoresistor made of monocrystalline cadmium sulfide. At this Photocell selection is the one cell translucent and can be over an area of the another cell between the common port or connection point and one end the other cell so that light passes through the top cell before it hits the other cell. The choice of the two cells can also be used be taken in such a way that the translucent cell is particularly visible on the outside the light lying in the red frequency range responds, while the partially covered Cell responds particularly to red to ultra-red light.

Details of a further embodiment of the invention emerge from the description of the exemplary embodiments shown in the drawing.

Fig. 1 is a schematic circuit diagram showing the arrangement of the Photocell arrangement in any detection device; Fig. 2 shows the diagram the response characteristics of the two cells R and B in the arrangement of Fig. 1; Fig. 3 is a perspective view of a somewhat simplified photocell arrangement; the blue cell overlying the red cell; F i g. 4 and 5 serve for explanation the effect of one on the embodiment of FIG. 3 transversely and longitudinally conspicuous Shadow; F i g. 6 is a plan view of a practical embodiment the photocell array; Figure 7 is a section along the line VII-VII in Figure 6; F i g. 8 is a section along the line VIII-VIII in FIG. 6; Fig. 9 and 10 are used to explain the manufacturing process of the FIG. 6 to 8 shown Photocell arrangement.

The schematic circuit diagram shown in Fig. 1 shows a device for detecting a flame, which with the cell arrangement according to the invention and between the ultra-radiation caused by a flame and other z. B. can distinguish ultrared radiation emanating from sunlight. The cell arrangement consists of the two photocells R and B between the two connection terminals t4 and t 5 are in series. The two cells share a common connection point tl and lateral external terminals t 2 and t3. If you close the two cells R and B to a voltage source not shown in the drawing, so act as a voltage divider that controls the voltage at the middle tap. These Voltage is passed on to a suitable amplifier A, which in turn provides a Relay, e.g. B. the winding K of a solenoid for operating a display device 1, for example a lamp, controls.

As can be seen from Fig. 2, the photocell R speaks in the following should be referred to as a red cell, predominantly due to the characteristic curve Rr indicated frequency band in the ultra red.

The cell R expediently consists of polycrystalline cadmium sulfide, however, lead sulfide, cadmium selinide and the like can also be used in this frequency range responsive connections are used. If one puts this connection to an ultrared radiation off, their conductivity increases. In the near ultra-red area, red cells become of cadmium sulfide, the response maximum of which, as can be seen from the curve Rr in F i g. 2 detects, at a wavelength below 1 es (1/100 mm). One such a cell has no scattering response characteristic to changes in ambient heat, for example atmospheric heat, as the wavelength of this radiation like also the radiation of the black body only in the far ultra-red range above of 1 p.

Cell B, referred to below as the blue cell, does not speak only to radiation of a frequency band that differs from the response range of the red cell on, but also in the opposite sense, d. H. by decreasing this responsiveness to the radiation in the frequency range in which the red cell responds. A cell which exhibits these properties, d. H. both a negative response characteristic in the area of the foreign frequency band as well as a positive response characteristic in the range of its own frequency band is monocrystalline cadmium sulfide. the normal response characteristic of cell B is indicated by the characteristic curve Rb 1 in FIG. 2, while their less deep response characteristics are different for two Infrared light intensities represented by the broken characteristic lines Rb 2 and Rb 3 is.

The cell arrangement operates in the device shown in FIG as follows: Assuming that the relay K is set so that it only works at a voltage above 10 volts, and that the input resistance of the Relay K and the signal or amplifier circuit A is about 1 MQ, that also R and B each have a certain resistance in the dark of about 100 MQ, and that to the circuit between terminals t4 and t5 a Voltage of 28 volts is applied, result in darkness, sunlight and for the pre If there is a flame next to sunlight the ones listed in the following table Values.

The resistance of the photocell B and the relay K connected in parallel corresponds approximately to the resistance of the parallel circuit and is approximately 1 MQ. Taking these variables into account, the result for the connection point t1 is a voltage of 0.28 volts, which is far below the response limit of the relay K, which is 10 volts. flame Dark, Sun and light solar light Impedance the red cell Zr ... 100 MQ 60 kQ 15 kQ Impedance of the blue cell Zb ... 100 MQ 10 kQ 15 kQ Zb and 1 MQ. . 1 MQ 10 kQ 15 kQ Voltage on tl ... 0.28V 4V 14V It can be seen from the table that the voltage at point t 1 in the dark is not sufficient to pull the relay K on. In sunlight, which is made up of both an ultra-red frequency component and visible light, the voltage has risen to one hundredth of the resistance of the parallel circuit of 1 MQ due to a decrease in resistance of photocell B. However, the resistance of the photocell R has also decreased, so that the voltage at the center tap t1 is only [101 (10 + 60)] 28 = 4 V. This voltage of 4 V is still below the response limit of relay K. If, however, the two photocells R and B are exposed to the light of a flame with a high proportion of ultra-red radiation, not only does the resistance of photocell R fall, it also increases Resistance of the photocell B, so that the voltage at the connection point tl [15 / (15 + 15)] 28 increases 14V and the relay K supplies a signal to the signaling device I.

In the case of the in FIG. The cell arrangement shown in Fig. 3 is the red cell R under the blue cell B and is provided with connections tl and t2. The connection tl represents a bridge to blue cell B, while terminal t 2 of a similar one Terminal t 3 of the blue cell is separated by an insulator C. The photocell arrangement 3 is designed so that on the red cell R incident light through the Blue cell B must pass through before hitting the red cell. Using monocrystalline cadmium sulfide for blue cell B has a filter effect due to the yellow to yellow-orange hue of this compound. How to get out of the dashed curve Y in FIG. 2, such a filter has a permeability which drops sharply against the response band Rb 1 of the blue cell. This increases the responsiveness of the red cell reduced to blue cell frequencies. This filter effect is the passage of near-infrared radiation not nearly as sharp cut.

As a result of this effect, there is an increase in red cell responsiveness on pure ultrared light compared to radiation which, for example Sunlight, has a substantial amount of blue and visible light.

As can be seen in particular from FIGS. 4 and 5, prevents the Arrangement according to FIG. 3 False displays due to shadows with a linear edge or also as a result of point shadows on one, but not on the other of the Cells fall. With the earlier photocell arrangements, the effect of a The blue cell, but not the shadow covering the red cell, for example, consist of that the resistance of the blue cell increased to 100mm, while that of the red cell in the Sunlight dropped to about 60 kOhm. With an impedance of the blue cell and the parallel cell Switching about 1 MQ, the voltage at point tl would be about 26 V and thus be big enough to trip the relay and give a false alarm in the process. at partial shadow formation according to FIGS. 4 and 5 on the photocell array according to the invention, this disadvantage does not arise. For example, comes to mind Shadows in the in F i g. 4 type shown with a straight edge parallel to an axis through the connection and t2 or t3 on the blue cell B, so have Parts of the blue cell and the red cell have a high resistance value, while parts both cells have a low resistance. As the two parts of both cells are parallel, a path with a relatively low resistance remains in each cell, so that the shadow cannot have any effect.

However, if the shadow falls in the FIG. 5 in the manner shown Arrangement so that it crosses the two cells between their terminals so has each cell has a high and a low resistance in series. Of the However, high resistance prevails in both cells, so that the same Effect as in the case where both cells are in the dark. Also in this In this case, the shadow cannot trigger a false alarm.

In the F i g. 6 to 10 is a particularly advantageous structure of the Photocell arrangement shown. The red cell R is located on a ceramic one Carrier disk S, which in F i g. 9 then has the shape shown in Fig. 10, conductive connections t 1, t2 and t3, for example in the form of a vapor-deposited Filmes, a frit or paste made of indium, gold or silver is applied, whereby the terminals t1 and t2 have their bases on opposite ends of the Red cell area are, while the connection t3 is located directly on the carrier S. Then a transparent one becomes at the exposed ends of the terminals t1 and t3 Blue cell crystal B "is attached. Thereby one end of the blue cell and one end the red cell is in charge connected to the common terminal or connection point tl, while the other ends are conductively connected to terminals t2 or t3, which are insulated from one another by the carrier disk S. The finished one, with one light-diffusing matt-ground glass pane 11 built into the tube 12 detector is shown in Figs. 8 to 10 shown.

While the blue cell B of FIGS. 3 to 5 is essentially complete is above the red cell R, the overlap in the arrangement according to FIGS. 6 to 10 not complete. However, erroneous effects become a shadow avoided by the ground glass 11 or some other scattering device, which cause a line or point shadow not only to fall on the blue cell can. It is also possible to arrange the cells side by side when using the diffuser eliminates any shadow, but this comes at the expense of sensitivity.

Claims (5)

Claims: 1. Photocell arrangement with at least two series-connected Photocells, in which the one cell (R) is particularly sensitive to radiation from a certain Frequency range (e.g. red) responds, while a second cell is particularly sensitive Radiation of a different frequency range (e.g. blue), characterized in that, that the excitation of the second cell (B) by additional radiation in the frequency range, in which the first cell (R) is particularly responsive (e.g. red), decreases. 2. photocell arrangement according to claim 1, characterized in that the first cell is a photoresistor made of polycrystalline cadmium sulfide, lead sulfide or cadmium selenide. 3. photocell arrangement according to claim 1 or 2, characterized in that that the second cell is a photoresistor made of monocrystalline cadmium sulfide. 4. photocell arrangement according to one of claims 1 to 3, characterized characterized in that the one cell is translucent and over an area of the another cell between the common connection or connection point and one End of the other cell so that light passes through one cell before it hits the other cell. 5. photocell arrangement according to claim 4, characterized in that the translucent cell especially on visible ones outside the red frequency range lying light appeals, while the partially covered cell is particularly sensitive appeals to red to ultra-red light. Considered publications: German Patent Specifications No. 639,853, 1,039,149; Swiss patent specification No. 329442.