DE1180555B - Counting and display device for electrical and optical pulses - Google Patents

Description

Counting and display device for electrical and optical pulses The invention relates to a counting and display device for electrical and optical Impulses by means of layers of substances whose electrical properties are determined by the Impulses are changed. Evaluation and counting devices are already more mechanical and electrical type known. The mechanical arrangements have the disadvantage that they are large and unwieldy and only a low evaluation speed due to the inertia to have.

The electrical counting devices used are mainly discharge tubes, especially gas-filled tubes, use. But these have the disadvantage that they are particularly technical in terms of production because of the required vacuum or the gas filling are difficult and time-consuming. In addition, they are easily prone to failure and only have a very limited lifespan.

These disadvantages of the known arrangements are in a counting and Display device for electrical and optical impulses by means of layers of materials, whose electrical properties are changed by the pulses, according to the invention avoided that evaluation cells, consisting of two electrically conductive, optically transparent coverings and at least one electroluminescent and a photoconductive layer, which are photoelectrically coupled to one another, in such a way that that after the pulse increases the conductivity of the photoconductive layer and the Electroluminescent layer has stimulated light emission, two more photoconductive ones Layers are influenced photoelectrically so that the one layer that on the Electroluminescent layer lying voltage of the previous cell decreases and the other layer forwards the pulse to the next evaluation cell and thus the number of pulses is counted and displayed.

The evaluation device according to the invention has the advantage that both their arrangement as well as the manufacturing technique are very simple. The single ones Layers of the evaluation units can be implemented in a simple manner, e.g. B. by spray or Printing process, to be produced in series. Furthermore, such is Arrangement, in contrast to the discharge tubes, can be produced in any size. The conductivity of the photoconductive layer can be determined by: an electrical impulse or a light pulse can be increased. The light pulse can e.g. B. by an electric Impulse which acts on an electroluminescent layer that is connected to the photoconductive Layer is optically coupled, are generated. But there is also the possibility that the conductivity of the photoconductive layer is increased in such a way by the pulse is that a layer is arranged whose resistance strength depends on the voltage is such that the pulse briefly reduces the resistance of the layer. Through this the electroluminescent layer of the evaluation unit is excited and still remains stimulated; when the counting pulse has long since died down. as The sulfides and selenides are particularly suitable materials for the photoconductive layer and tellurides of zinc, cadmium or lead. The stress-dependent layer can be in advantageously consist of cadmium sulfide or silicon carbide. The invention provides for the luminous effect of the electroluminescent layer to display the To use counting status. The evaluation status can be identified by Characters, such as numbers or letters, which are in the form of a screen in front of the electroluminescent Layer are attached. The photoconductive layers, which with each neighboring counting or evaluation units are coupled, can in a simple manner be applied directly to the electroluminescent layer. This is a very close electrical coupling ensured.

Exemplary embodiments of the invention are based on the basic sketches explained in more detail.

On a suitable, optically transparent base 1 of FIG. 1, which z. B. consists of glass or mica, there is an electrically conductive, optically transparent layer 2. This layer 2 is followed by a photoconductive layer 3 and an electroluminescent layer 5. On this layer, in turn, an electrically conductive, optically transparent layer 6 is arranged, which can be designed in certain predetermined shapes, such as characters or letters. A part of the surface of the electroluminescent layer 5 faces further photoconductive layers 13 and 16. These layers are between two electrically conductive layers 12 and 14 or 15 and 17 on an opti: --h transparent base 1 a and 1 b, e.g. B. G13s ccier mica attached. The conductive layer r 5 or 12 is transparent to the radiation emitted by the layer 5. There are several of these units described in FIG. 1 arranged manner shown. The evaluation elements are each optically shielded from one another in such a way that no undesired photoelectric effects or couplings, in particular from external light sources, can occur. The shield 19 is indicated by oblique hatching. The conductive layers 15 are coupled to the conductive layers 2 and the layers 2 and 6 are coupled to the layers 12 and 14 of the respective following cells. The voltage which excites the luminescence of the layer 5 is applied to the terminals 11, which are connected to the layers 6 and 17 of the individual elements. The number 24 denotes a light source whose light pulses are to be counted with the evaluation device. This light source 24 can, for. B. an electroluminescent cell, a gas discharge tube, a spark gap od. Like. Be.

In the following consideration, a state is assumed in which the electroluminescent layer 5 of the cell I is excited to emit. Falls Another light pulse from the generator 24 is generated in cells I1, 111, etc. the electrical conductivity of the respective photoconductive layers 3 is increased. It However, excitation of the luminescent layer can only occur in cell 1I 5 take place, since only in this case the photoconductive layer 16 of the cell 1 a has sufficient conductivity to the threshold value of the electroluminescence excitation to overcome. The high conductivity of the photoconductive layer 16 results from the luminescence excitation of cell I. When cell II is excited, a Excitation of the photoconductive layer 13 of this cell, which in turn affects the Conductive layer 2 and 6 of the cell I effective voltage lowers so far that it is below the threshold value of the luminescence excitation of this cell drops. The cell is then extinguished I. In the same way, another light pulse will stimulate the luminescence on the Cell III transferred, cell II going out. The one corresponding to the light pulse Numerical value can be assigned directly to the corresponding luminescent cell. A simple way of marking can be achieved in such a way that before the Cell an aperture 23, which takes the shape of suitable numbers, characters or letters has, is attached.

Another embodiment is shown in FIG. 2. It differs from the exemplary embodiment in FIG. 1 essentially in that the evaluation process is triggered by electroluminescent layers which are assigned to the individual cells. The same reference symbols are used for the same parts. The conductivity of the photoconductive layers 3 of the individual cells is excited by an electroluminescent layer B located between two electrically conductive layers 7 and 9 on the base 1. The layer can be excited to electroluminescence by a voltage pulse applied to the terminals 10 to be counted. The base 1 is substantially transparent to the radiation emitted by the layer 8 and consists, for. B. made of glass, mica and the like. On the other side of the base 1 is a radiation-permeable, electrically conductive layer 2, a photoconductive layer 3, an electrically conductive layer 4, an electroluminescent layer 5 and an electrically conductive layer 6, which the radiation emitted by the layer 5 transmits, attached.

On part of the surface of the layer 6 there are two further substrates 1 a and 1 b, which are transparent to the radiation emitted by the layer 5. On each of these substrates and between two electrically conductive layers 12 and 14 or 15 and 17, photoconductive layers 13 and 16 are applied. The voltage pulses to be counted applied to the terminals 10 are each transmitted via the photoconductive layers 16 to the electroluminescent layer 5 of the subsequent cell. At the terminals 11 is the layer 5 stimulating luminescence voltage, z. B. AC voltage. Assuming that the layer 5 of the cell I is excited to luminescence, the result, since the photoconductive layer 16 of the cell I has a high conductivity, an excitation of the electroluminescent layer 8 of the cell 11. As a result, the electrical conductivity of the photoconductive layer 3 is reduced to such an extent that the voltage threshold value of the luminescence excitation is exceeded. The cell II is thus also stimulated to permanent electroluminescence. The photoconductive layer 13 of this cell is given such a high electrical conductivity by the irradiation of the layer 5 that the voltage effective at the layers 4 and 6 of the cell 1 drops from the threshold value required for the electroluminescence excitation and the excitation of the cell I is interrupted. In the same way, if a further voltage pulse occurs at the terminals 10, the luminescence excitation is passed on to the cell fII, etc. The electroluminescent layer 5 of the cells is, as indicated in the figure by punctuation, only applied to a certain area of the layer 4 , that the electroluminescent part corresponds to the character to be displayed for the evaluation status, such as a number or letter.

Another embodiment is shown in FIG. 3 shown. In this embodiment, the voltage pulse to be counted acts in a direct manner on the electroluminescent layer which displays the count value. Here, one after the other over the radiolucent base 1, the electrically conductive layer 6, the electroluminescent layer 5, a photoconductive layer 3, a further layer 25, the resistance of which decreases significantly from a certain voltage value, and an electrically conductive layer 7 are arranged. The voltage-dependent resistance layer can, for. B. consist of suitably prepared cadmium sulfide. The conductive layers 6 and 7 are each connected to the terminals 10 and 11 via a resistor 26. The arrangement of the layers corresponds, apart from the fact that they are mounted on a common carrier, to that shown in FIG. 1 and 2 illustrated embodiments. On the carrier 1 there is an optical diaphragm, the recesses of which correspond to the character to be displayed for the cell in question. When a voltage pulse is applied to terminals 10, when cell 1 is excited, due to the high conductivity of photoconductive layer 16 of this cell on voltage-dependent resistance layer 25 of cell II, the threshold value is exceeded and electroluminescent layer 5 of cell II is excited to emit. This increases the conductivity of the photoconductive layer 3 of this cell so high that the threshold value for the voltage applied to the terminal 11, e.g. B. AC voltage; is exceeded and thus the luminescence excitation is maintained even after the voltage pulse has decayed.

As a result of the increase in the conductivity of the photoconductive layer 13 of the cell 1I becomes the one on the conductive layers 7 and 6 of the cell I with the assistance of the suitably dimensioned resistor 26 reduces the voltage to such an extent that that the voltage effective at layer 5 drops below the threshold value. The emergency deletion the luminescence is given suitable dimensioning of the resistance values of the layers still supported by the fact that the voltage-dependent resistive layer 25 effective voltage drops so far that the resistance of this layer in strong Dimensions is increased. In the event of a further voltage pulse applied to terminals 10 the luminescence excitation from cell 1I to cell III is in the same way passed on etc.

Another embodiment in which, in contrast to the previous The cells are not arranged next to one another, but one behind the other FIG. 1 shows. 4. On a see-through, at least for that of the cells emitted light-permeable base 1, which again z. B. made of glass or mica can consist is a transparent, electrically conductive layer one after the other 6 and an electroluminescent layer 5, an electrically conductive layer 4, a photoconductive layer 3 and an electrically conductive layer 2 attached. the electroluminescent layer 5 has in the present embodiment Peculiarity that it is essentially transparent. Such a layer can be achieved in a known manner in that the substrate is contaminated with Mn Zinc fluoride evaporated and the evaporated layer in a stream of hydrogen sulfide is converted into manganese activated zinc sulfide. The electrically conductive layer 6 is on part of the base 1 in the form of a character, in particular one Number, upset. When using a base made of glass or mica can this z. B. achieve that a panel is attached in front of the heated pad which corresponds to the character to be represented and that vapors of tin tetrachloride directed at the base or a suspension of tin dichloride on the base is sprayed.

The photoconductive layers 13 and 16 located between the electrically conductive layers 15 and 17 or 12 and 14 are located in particular on the substrate 1. The optical shields prevent undesired optical couplings between them. The voltage pulses to be counted are applied to terminals 10 and the voltage which excites the electroluminescence of the cells, e.g. B. AC voltage placed. The electrically conductive layers 15 are to be counted with the pulse voltage; the electrically conductive layers 17 are connected to the electrically conductive layer 2, which is located on the photoconductive layer J: n the same conductive layer, the voltage at the terminals 11, which excites the electroluminescence of the layer 5, is applied via a resistor 26. The electrically conductive layers 12 and 14 are connected to the electrically conductive layers 4 and 6 of the cell that was behind in the counting process: when a voltage pulse is applied to the terminals 11, the pulse is transmitted via the photoconductive layer 16 to a cell that is in excitation electrically conductive. Layers 2 of the next cell. This exceeds the threshold value of the electroluminescent excitation of the layer 5 of this cell, causes the electroluminescent layer 5 to emit light and the conductivity of the photoconductive layer is increased to such an extent that the further excitation even after the voltage pulse has subsided by the effective via the resistor 26; at the terminals 11, applied voltage is maintained: The verbuüdene increase in the conductivity of the photoconductive layer 13 of this cell causes a decrease in the electroluminescent layer of the. previous cell effective voltage below the threshold value. The excitation of the previous cell is thus canceled. In the same way, the 1 'uminescence excitation is transmitted to the next cell in the event of a further voltage pulse.

The invention is not only suitable for displaying evaluated states, but also for having electrical controls related to the display or to be carried out with the omission of the optical display.

Claims (14)

Claims: 1. Counting and display device for electrical and optical pulses by means of layers of substances whose electrical properties are changed by the pulses, characterized in that evaluation cells (I, II ... ), consisting of two electrically conductive, optically transparent coverings ( 2 and 6) and at least one electroluminescent layer (5) and one photoconductive layer (3) are photoelectrically coupled to one another in such a way that after the pulse has increased the conductivity of the photoconductive layer (3) and has stimulated the electroluminescent layer (5) to emit light , two further photoconductive layers (13 and 16) are photoelectrically influenced in such a way that one layer (13) reduces the voltage of the previous cell on the electroluminescent layer (5) and the other layer (16) passes the pulse on to the next evaluation cell and thus the number of pulses is counted and displayed. 2. Device according to claim 1, characterized in that that the increase in the conductivity of the photoconductive layer (3) by the pulse takes place by means of a further electroluminescent layer (8), which with the photoconductive layer (3) is optically coupled. 3. Device according to claim 1, characterized in that the increase in conductivity the photoconductive Layer (3) takes place through the pulse by means of a layer (25), the resistance of which is strongly voltage-dependent in that the impulse increases the resistance of the layer (25) briefly reduces and thus the electroluminescent layer of the evaluation unit is excited and is still excited when the impulse has long since died down is. 4. Device according to claim 1, characterized in that; that the to light emission excited electroluminescent layer (5) of the cell at the same time the evaluation state indicates. 5. Device according to claim 1 and 4, characterized in that the electroluminescence = rende layer (5) is arranged in such a way that the luminous effect takes the form of characters, like letters or numbers. 6. Device according to claim 5, characterized characterized in that the electroluminescent layer (5) in the form of characters, such as letters or numbers. 7. Device according to claim 1, characterized characterized in that the electroluminescent layer (5) following the electrical Conductive layer (6) is applied in the form of characters, such as letters or numbers. B. Device according to Claim 1, characterized in that the photoconductive layer (3, 13, 16) from sulphides, selenides or tellurideri 'of zinc, cadmium or lead consists. 9. Device according to claim 3, characterized in that the voltage-dependent Layer (25) consists of CdS or silicon carbide. 10. Device according to claim 1, 4 and 5, da4. characterized in that the photoconductive layer (3) has the property an electroluminescent layer. 11. Device according to claim 1, characterized in that the electroluminescent layer (5 or 3) is transparent is. 12. Device according to claim 1, characterized in that the electroluminescent evaluation units (I, t1, III ... ) are arranged one behind the other. 13. Establishment according to claim 1, characterized in that the electroluminescent evaluation units (I, 1I, 11I ...) are arranged side by side. 14. Device according to claim 1, characterized in that the evaluation units are optically covered from one another are that no strengthening optical coupling occurs. Considered publications: Proc. I. R. E., October 1953, pp. 1393 to 1406.