DE2548288C3 - Two-pole display circuit - Google Patents

Description

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The invention relates to a two-pole display circuit for a DC voltage threshold value in which between the poles of the DC voltage source is the series connection of a semiconductor luminescent component and a Schmitt trigger controlled by the DC voltage is connected

Semiconductor arrangements have already been proposed which consist of a series connection of a resistor w> des and a light emitting diode. This made it possible to connect a lighting component to a supply voltage source to be connected, the voltage value of which differs from the operating voltage of the diodes. In these arrangements, however, the one indicated by the »"> Luminous element flowing current and thus also the luminous intensity depends on the voltage. Furthermore, from the DE-OS 20 60 045 a charge control circuit is known in which a luminescent diode has a Schmitt trigger is connected upstream, but this circuit also has the disadvantage that for adapting the luminescent component voltage dividers are required for the supply voltage and the light intensity depends on the voltage is

The present invention is based on the object • to provide a display unit in which the Display by a luminescence semiconductor component, in particular a light-emitting diode, takes place Luminescent component only causes the glow above a certain voltage value Conducts current, which then remains constant even with increasing voltage two-pole housing can be accommodated. According to the invention, the stated object is thereby achieved solved that the Schmitt trigger a constant current generator connected in series with the luminescent component is followed by the Schmitt trigger only when a certain DC voltage threshold value is exceeded is switched on and that the luminescent component and the circuit of the constant current generator and Schmitt trigger is housed in a common housing that consists of consists of translucent plastic and has two connecting poles

The new display circuit can, in particular, be used to monitor the discharge status of a battery would be used because when the battery voltage drops below a certain threshold value, the current is switched off by the luminescent component, so that the illuminated display goes out. The circuit part from the constant current generator and the Schmitt trigger is advantageously in a single monocrystalline semiconductor body housed in the form of an integrated solid-state circuit This integrated The circuit is attached, for example, in the plastic housing to one of the housing leads, while the light-emitting diode is arranged on the other housing lead. The light-emitting diode and the integrated circuit are electrical, for example via a thin bonding wire conductively connected to each other. The two housing leads are connected to the poles of the DC voltage source.

The constant current generator consists of two transistors T ₃ and T ₄ , the base-emitter path of a transistor 71 provided with an emitter resistor Re being bridged by the collector-base path of the other transistor T ₃ provided with a collector resistor Rc. The resistor Rc and the collector of the The transistor T ₄ is connected to one pole of the DC voltage source and the resistor Re and the emitter of the transistor T _{3 are} connected to the luminescent component. The output of the Schmitt trigger, by means of which the constant current generator is switched on or off, is also connected to the base of the transistor Ta.

The invention is to be explained in more detail using an exemplary embodiment.

In FIG. 1 shows the circuit comprising the Schmitt trigger S, the constant current generator K and the luminescent diode L. The Schmitt trigger and the constant current generator are connected in parallel, the output of the Schmitt trigger being additionally connected to a control input of the constant current generator. The parallel connection of Schmitt trigger and constant current generator is in series with

LED L switched The series connection is between the poles of the DC voltage source.

The Schmitt trigger S consists of the two transistors Ti and Tj, wherein the collector-emitter path of the transistor Ti bridged by the base-emitter path of the output transistor T _2, the base voltage potential of the transistor Ti is connected to the base voltage divider comprising resistors R \ and R ₂ The transistor Ti is provided with a collector resistor R ₄ and an emitter resistor / I ₃ . The resistors R \ and A3 are connected to the light emitting diode L and the resistances R2 and _R4 connected to the positive pole of the DC voltage.

The structure of the constant current generator K has already been described. Since only npn transistors are used in the illustrated embodiment, Rc and the collector of Ti are also connected to the positive pole of the DC voltage source.

If the Schmitt trigger is disregarded, the constant current generator works as follows: At low voltage values {/ T _{4 is} conductive and T _{3 is} blocked. A current / increasing with voltage U flows through T ₄ and Re. At a certain voltage value U * , a voltage sufficient to turn on transistor T ₃ drops across Re. This is the case with a voltage drop of approx. 0.7 V across Re . The current / * delivered by the constant current generator can no longer increase when the transistor T3 is switched on, so that the current / * always flows through the luminescent diode L even if the voltage LJ continues to increase, thus causing a voltage-independent, always constant light intensity

The Schmitt trigger is dimensioned so that the transistor Tj is conductive up to the voltage U * . If the voltage values are below U * , Γι is blocked, so that a high potential is applied to the base of Ti , which controls transistor T ₂

If the voltage i / exceeds the value U *, then a voltage that controls this transistor drops at the base of Ti. The collector potential of Γ, and thus the base potential of Ti then drops so much that the transistor Ti is blocked.

At voltage values below U * , such a large current component flows through the collector of the conductive transistor T ₂ that the base current remaining for the transistor T _{4 is} not sufficient to control it through. Since the switching on of the Schmitt trigger means that the transistor T ₄ remains blocked at low voltage values, the constant current generator K does not emit any current at voltages below U *. Only when! T _{2 is} blocked does T _{4 become} conductive. Then, however, a voltage which controls transistor T ₃ through already drops at R _E , so that the final current / * is emitted immediately after the constant current generator has been switched on.

The described i // A characteristic curve through the luminous element L results from FIG. 2. For voltages below U *. for example at 4 V, no current flows. At the When U * is reached , the current rises steeply to the value / * and then remains constant with increasing voltage

In Fig.3 the housing for the described Circuit shown The Schmitt trigger S and the Constant current generator K are housed in a common semiconductor body IC . This semiconductor body is attached in an electrically conductive manner to the end face of a housing lead 1 to be connected to the positive pole of the DC voltage source The end face of the other housing lead 2, which is to be connected to the negative pole of the DC voltage source, the luminescent diode L is arranged to be electrically conductive. The two semiconductor units are electrically conductive via a thin lead wire connected with each other. The lead ends are Potted with the semiconductor components in a plastic housing 3, which is translucent and is preferably designed lens-shaped (4) to increase the light yield

The integrated circuit must with the described structure with the positive pole of the voltage source get connected. One must therefore start from an η-conductive semiconductor base body in order to achieve a To achieve blocking of the separation pn junctions. In p-zones are therefore diffused into the η-conducting base body as »burried-layer« zones η-conductive base body, an epitaxial, η-conductive layer is then deposited into which to achieve insulated, n-conducting tubs up to the »burried-layer« Zone-reaching p-type separation diffusion zones are diffused in, which completely enclose an η range. In this η-conductive, tub-shaped The components of the integrated circuit are then diffused into areas

With this technology, resistors and transistors whose collectors may be connected to the n-semiconductor base body (e.g. Ta) can be diffused into the semiconductor body without separation.

1 sheet of drawings

Claims (5)

Patent claims: 1. Two-pole display circuit for a DC voltage threshold value, in which between the poles of the DC voltage source, the series circuit of s a semiconductor luminescent component and a DC voltage controlled Schmitt trigger is connected, characterized in that the Schmitt trigger (S) with the luminescent component (L) is followed by a series-connected constant current generator (K) , which is only switched on by the Schmitt trigger (S) when a certain DC voltage threshold value is exceeded and that the luminescent component (L) and the circuit of the constant current generator (K) and Schmitt -Trigger (S) housed in a common housing (3), which consists of translucent plastic and has two connecting poles (1,2) 2. Display circuit according to claim 1, characterized by its use as a battery charge control. 3. Display circuit according to claim 1 or 2, characterized in that the luminous element is a light emitting diode 4. Display circuit according to claim 1, characterized in that the circuit of the constant current generator (K) and the Schmitt trigger (S) is housed as an integrated solid-state circuit in a semiconductor body which is fastened in the plastic housing on one housing supply line and with that on the other Housing lead attached luminescent diode is electrically connected 5. Display unit according to one of the preceding claims, characterized in that the constant current generator (K) consists of two transistors T ₃ , 71, the base-emitter path of the one provided with an emitter resistor R _E transistor 7} from the collector-base path of the with a collector resistor Rc provided other transistor T _{3 is} bridged, that the resistor Rc and the collector of the transistor T _{4 is} connected to one pole of the DC voltage source and the resistor Re and the emitter of the transistor T _{3 is} connected to the luminous element L and that to the Base of transistor Γ ₄ the output of Schmitt trigger K is connected.