EP1096834A2 - Display device with luminescent elements - Google Patents

Abstract

Semiconductor components (Dij) are wired in multiple circuit groups, each group forming a subsidiary branch of current. A circuit is assigned to a constant power device (3) so that the sum of partial electrical currents flowing in subsidiary branches has a pre-determined constant value.

Description

The invention relates to a display device according to the preamble of claim 1, in particular for use in a system for traffic regulation, control or monitoring for vehicles, for example in a traffic light.

Although such a display device is designed for the longest possible service life and has been tested, like all other lights, it is subject to certain failures that impair or can lead to the shutdown of the display device. Especially here particularly relevant cases in which the display device to prevent damage on people or vehicles or objects, i.e. used as a safety signal, there must be a monitoring device assigned to the display device, which recognize a defect in the display device and corresponding immediate Measures should activate.

Especially in the case of a generic display device with several on one carrier arranged lighting elements, the lighting elements by semiconductor components and are constructed in particular by light emitting diodes, is the constructive and circuitry The expense of such a monitoring device is disadvantageous. As is well known, one has Semiconductor components compared to such light fields formed from incandescent lamps one more homogeneous over the entire surface and thus clearer from a distance Recognizability above all the advantage that only a very large number of defective light-emitting diodes become one cause noticeable loss of information. By a suitable wiring of the LEDs and formation of the circuit controlling this can even with several defects of the Light emitting diodes prevent a decrease in the overall light intensity. By the decentralized Arrangement of the rows of light-emitting diodes switched in groups can also be avoided parts of the illuminated field become dark. For example, any individual row of LEDs can be monitored individually for failure and when exceeded a certain limit, for example if the LEDs are defective by more than 20% Display device can be completely switched off via an automatic switch-off.

In contrast, the monitoring of incandescent lamp arrangements is essential in terms of circuitry Simpler: Since only the two operating states are intact with incandescent lamps (filament OK) and defective (filament has burned out), but no intermediate states in the characteristics of a display device based on incandescent lamps are Monitoring devices are extremely simple in terms of circuitry and are limited in Essentially on the determination of a binary yes-no state. The one at traffic lights with incandescent lamp signals previously used, extremely constructive and circuit-wise simply constructed monitoring devices are, however, in such display devices, in which the lighting elements are formed by semiconductor components, so far not useable.

The failure characteristics of previously known display devices with semiconductor components as lighting elements is much more complex than a simple failure characteristic of incandescent lamp assemblies. With the known monitoring options can without a special, considerable circuit effort, not clearly on the lighting state one of the LEDs can be closed. Because that for the function of LEDs required control, the lighting circuit itself and any other modules or modules of the monitoring device also necessarily have their own power consumption, which is undefined in the event of a defect and can generate a current flow which is as (proper) glow can be interpreted, although one or more already LEDs have failed. In certain applications, such as traffic lights in particular it is additionally necessary to ensure that there is a minimum radiation intensity and a minimum uniformity of the illuminated field is maintained. The current flow changes are usually relatively small, so that the residual light intensity and the Uniformity of the luminous field may not be precisely determined and therefore possibly a safety shutdown cannot be performed reliably.

Take into account the known display devices based on semiconductor components usually only so-called high-resistance failures, in which the defective semiconductor component becomes high impedance, d. H. the current flowing through the defective semiconductor device Zero. Low-resistance failures in which the resistance value of the defective semiconductor component Becomes zero, are generally neglected with known display devices, since these are less common in relation to high-resistance failures. Nevertheless it would be desirable in itself, also the less common low-resistance failures of semiconductor components can also be considered to ensure the safety of the display device continue to improve.

The invention has for its object a display device of the generic type Type in which the lighting elements are designed as semiconductor components to be put in a plant for traffic regulation, control or monitoring for vehicles, in particular a traffic light in connection with the conventional ones there structurally simpler monitoring devices for recording a total failure the display device can be used, d. H. the display device after the The invention is said to have a failure characteristic that largely corresponds to the failure characteristic of incandescent lamp arrangements.

The problem is solved with the characterizing features of claim 1.

According to the invention, it is provided that the semiconductor components Circuit of a constant current device is assigned such that the sum of the in electrical sub-currents flowing in the secondary branches have a predetermined constant value owns. Of particular advantage is the constant current device by a single Main branch of the constant current source provided from the circuit formed by the semiconductor components educated.

Following the principle of the invention is a control circuit device assigned to the semiconductor components provided that if a flowing in a secondary branch is exceeded Partial current around a predetermined current threshold a blocking or deactivation of the relevant branch, and after exceeding a predetermined number a blocking of blocked or deactivated secondary branches in immediate succession or deactivation of all other secondary branches and thus the entire display device controls.

Glühfadenbruch" erfasst.With the circuit arrangement according to the invention, on the one hand, it is possible that no undetected weakness in luminosity, which is unsafe for safety reasons, occurs during operation due to the failure of individual lighting elements. If, on the other hand, individual lighting elements fail over time due to a high-resistance interruption, the overall luminosity of the display device is hardly weakened, because a larger partial current is applied to the secondary branches of lighting elements that are still in operation, thereby compensating for the loss of luminosity . Even the failure of one or more secondary branches does not yet lead to a total failure of the display device, since the partial currents in the remaining, still intact secondary branches are automatically raised to such an extent that the light intensity emitted by the still intact lighting elements is increased and that due to the failure of one or weakening of luminosity associated with several secondary branches is compensated. Only after a predetermined number of blocked or deactivated secondary branches has been exceeded will a fuse element in a specific secondary branch respond due to the excessive partial current now flowing therein, and will ultimately trigger the fuse elements of the remaining secondary branches of lighting elements and bring the display device to automatic shutdown. The display device then delivers a failure signal which can be detected by a monitoring device. The invention is based on the finding that if a partial current flowing in a secondary branch is exceeded by a predetermined current threshold value, not only does the affected group of lighting elements fail, but there is an abrupt blocking or deactivation, that is to say at extremely short time intervals that are barely measurable all other secondary branches and thus the entire display device, and in this way the display device according to the invention has a failure characteristic that is comparable to a failure characteristic known in the case of an incandescent lamp arrangement. Of particular advantage, the display device according to the invention can therefore be coupled directly and without further constructive or circuitry measures and expenditure to a monitoring device previously used in systems for traffic regulation, control or monitoring, which monitors a total failure of the display device via a simple current evaluation as in one

Filament breakage "detected.

The invention eliminates the need to regularly check the current lighting status the display device by measuring current flow changes. With the invention Display device is created in a safe and clear situation of which only two conditions have to be determined, namely whether current flows in the main branch and thus a safe overall light signal that is uniformly defined in terms of brightness and luminance exists, or no current flows in the main branch or that the display device does not more shines. Small current changes that are difficult to measure do not have to be monitored, as is the case with the prior art.

Another advantage is that the display device according to the invention is flexible can be handled by designing the control circuit device and the individual fuse elements in each secondary branch of the semiconductor components formed circuit can be determined exactly at which light field decay the display device should switch off automatically.

By assigning a single fuse element in each secondary branch from the Semiconductor components formed circuit is achieved that after failure of a predetermined Percentage of groups of lighting elements due to overloading of the fuse elements the still functioning current paths automatically the entire display device switches off and the situation is brought into a safe state. In order to the failure can be signaled in the usual way via a known monitoring device to be able to arrange for the replacement of the display device.

The display device according to the invention is not only capable of high-resistance failures of semiconductor components, but now also takes into account low-resistance failures be, whereby the security of the display device is further increased. A high impedance Failure of a light element causes the total electrical resistance of the affected Secondary branch is infinite and the partial current flowing therein becomes zero. The partial flows in the remaining secondary branches rise accordingly, accompanying this with the increase in light intensity, etc. as described above. With a low impedance Failure, however, the branch in question remains intact overall; it flows in Partial current that is only slightly lower than before the low-resistance failure. Only with several low-resistance failures, the partial current in the relevant branch is so large that the safety element in question triggers and the secondary branch concerned completely locks or deactivates.

According to the principle of the invention, it is provided that the constant current source device by a single in the main branch of the circuit formed from the semiconductor components provided constant current source is formed. In principle, any suitable ones are suitable Circuits for such a constant current source. A technically simple and Inexpensive constant current sources are achieved with a transistor whose base is based on a predetermined control voltage and its collector on a main current line or in Main branch of the circuit formed from the semiconductor components is connected. The An electrical resistance determining the current is assigned to the emitter. Such Constant current source has the advantage that it is not based on a specific circuit of the display device is restricted.

Advantageous developments of the invention result from the subclaims.

Figur 1

ein schematisches Schaltbild einer Anzeigevorrichtung nach einem bevorzugten Ausführungsbeispiel der Erfindung;

Figur 2 A und 2 B

schematische Vorder- und Schnittansichten der Anzeigevorrichtung nach dem Ausführungsbeispiel; und

Figur 3

eine schematische Darstellung der Ausfallcharakteristik einer Anzeigevorrichtung nach dem Ausführungsbeispiel.

Further features, advantages and expediencies of the invention result from the following description of an embodiment of the invention with reference to the drawing. It shows:

Figure 1

a schematic diagram of a display device according to a preferred embodiment of the invention;

Figure 2A and 2B

schematic front and sectional views of the display device according to the embodiment; and

Figure 3

is a schematic representation of the failure characteristic of a display device according to the embodiment.

The embodiment shown in the figures shows a display device according to the invention 1 for a changing information, the information by selection or Combination of individual lighting elements L arranged on a carrier T is shown is, and the lighting elements L are formed by semiconductor devices Dij, in particular from light emitting diodes or other integrated semiconductor circuits with components for Light emission. The semiconductor components Dij are in several circuit groups, shown in Case 24 of such groups, with only six groups shown in more detail, switched, each circuit group current-wise a secondary branch N1, N2, ..., N6 of a main branch H forms with node K. In each secondary branch Ni there is a multitude of light elements, for example, a number of ten lighting elements Di1 to Di10 connected in series (i denotes the number of the group or branch, j the number of the Light element in the secondary branch). The consisting of the semiconductor devices Dij Circuit is assigned to a constant current device 3 such that the sum of the in the sub-branches N1, N2, ... electrical partial currents flowing a predetermined constant Has value, regardless of the flow in the secondary branches Partial flow values. It is a control circuit device assigned to the semiconductor components Dij F is provided which, if one in a secondary branch N1, N2, ... is exceeded flowing partial current around a predetermined current threshold a blocking or deactivation of the relevant branch, and after exceeding a predetermined Number of blocked or deactivated secondary branches in immediate succession one Blocking or deactivating all other secondary branches and thus the entire display device 1 controls. In the exemplary embodiment shown is the control circuit device F by individual fuse elements F1, F2, ... in each secondary branch N1, N2, ... the circuit formed from the semiconductor devices Dij. These security elements in the simplest case provide fuses with predetermined breakdown current values represents, for example with 125 V / 50 mA each with a number of 24 independent Luminous element groups of 10 LEDs each, the total current in the main branch (operating current the constant current source 3) is typically 0.5 A.

Via connecting lines 4 and 5, the display device 1 according to the invention is connected to the potential U + or ground potential GND of a DC supply voltage and to a monitoring device 2 previously used in systems for traffic regulation, control or monitoring, namely the monitoring device 2 is connected to the Primary side of a transformer or a transformer Tr coupled, the secondary side of which is coupled to the circuit according to the invention via a rectifier G1. The peculiarity of the display device 1 according to the invention is precisely that it can be coupled to a monitoring circuit 2, which has hitherto been used in traffic lights, and which monitors a total failure of the display device 1 via a simple current evaluation, as in a case Broken filament ".

The functioning of the display device 1 according to the invention is as follows. In normal operation flows over each branch branch N1, N2, ... through the series connection of light-emitting diodes a group and one provided in each branch, the adaptation of the branches with each other due to manufacturing tolerances serving ohmic resistance R1, R2, ... determined total resistance of the specified partial current, the sum of all partial currents flowing in the secondary branches equal to that from the constant current source 3 delivered total constant current in the main branch H is. A high-resistance failure A lighting element Dij has the result that the entire group i or the secondary branch Ni fails, d. H. the partial current flowing in the secondary branch Ni becomes zero. As a result, the partial flows flowing in the remaining secondary branches assume higher values and correspondingly the luminosity of the luminous elements loaded with a higher partial current increases. Luminosity weakening due to failure of one or more groups or secondary branches is thus due to a larger current surcharge of those still in operation Secondary branches compensated. The total current is thus divided between the remaining branches while raising the partial flows. A progression of the failures of lighting elements leads to successive increases in the partial flows until the partial flows The nominal value of the safety elements F1, F2, ... exceed, and this an avalanche-like interruption of the remaining circuits and thus the main branch. For the invention Function of the display device is therefore essential that the failure characteristic the display device according to the embodiment approximately that of an incandescent lamp arrangement corresponds to how it is based on the schematic characteristic curves 7, 8, 9 in FIG. 3 is shown. In the diagram according to FIG. 3, the time t is plotted to the right, the Time axis is not shown linearly, but the three areas that are completely different in time Year range, hour range and millisecond range. Up are in arbitrary units each have the physical parameters total current, total light intensity and number of intact rows, or secondary branches, where for reasons of the respective 100% values are arranged offset so that they can be better represented. You watch four areas A, B, C and D in the characteristic curves 7, 8, 9. Area A corresponds to the normal one Operating state of the display device without any failure, in area B shows the gradually increasing failure of some individual lighting elements or secondary branches, which, however, is not yet an undetected luminosity weakening that is questionable in terms of safety results in area D being the total failure of the display device specified. The transition area C with an almost vertical flank is interesting below, which is only the sudden failure of the entire display device after triggering a further securing element deactivated after exceeding the predetermined number Identifies secondary branches.

This state can be registered by means of a monitoring device 2 customary in technology and reported to a head office. The staff is then asked to identify the person concerned Exchange display device.

Claims (10)

Display device for changing information, the information being represented by selection or combination of individual light-emitting elements (L) arranged on a carrier (T), the light-emitting elements being formed by semiconductor components (Dij), in particular composed of light-emitting diodes or other integrated semiconductor circuits Components for light emission, and the semiconductor components (Dij) are connected in several circuit groups, and each circuit group forms a secondary branch (Ni) in terms of current of a main branch (H),
characterized in that
the circuit consisting of the semiconductor components (Dij) is assigned to a constant current device (3) such that the sum of the partial electrical currents flowing in the secondary branches (Ni) has a predetermined constant value. Display device according to claim 1, characterized in that the constant current device (3) by a single one in the main branch (H) consisting of the semiconductor components (Dij) constant current source provided circuit is formed. Display device according to claim 1 or 2, characterized in that one of the semiconductor components (Dij) associated control circuit device (F) is provided, which at Exceeding a partial flow flowing in a secondary branch by a predetermined one Current threshold a blocking or deactivation of the relevant branch, and after exceeding a predetermined number of blocked or deactivated secondary branches a blocking or deactivation of all other secondary branches in immediate succession and thus controls the entire display device (1). Display device according to claim 1 to 3, characterized in that the control circuit device (F) through individual securing elements (Fi) in each secondary branch (Ni) the circuit formed from the semiconductor components (Dij). Display device according to claim 4, characterized in that the securing elements (Fi) formed by fuses with predetermined breakdown current values are. Display device according to claim 5, characterized in that the semiconductor components (Dij) of a branch (Ni) side by side in a row and with the corresponding one Fuse element (Fi) are connected in series. Display device according to claim 6, characterized in that the secondary branches (Ni) are connected in parallel to each other and branch off from the main branch (H) at a node (K). Display device according to claim 1 to 7, characterized in that it is in a system for traffic regulation, control, or monitoring for road vehicles, in particular is used in a traffic light. Display device according to claim 8, characterized in that the system for traffic control, Control or monitoring one of the display device (1) downstream Monitoring device (2), which has a total failure of the display device (1) recorded. Display device according to claim 9, characterized in that it is on the output side provides a monitoring signal for the monitoring device (2), which two different has electrical states, the one state, operating state, a proper Operation of the display device (1) and the other state, fault state, corresponds to a total failure of the display device (1).

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