EP0463387A2 - Power supply for a pre-heating device of a pre-heated display, especially of a fluorescent display - Google Patents

Abstract

A power supply for a heating device (20) of a heated display (10), especially of a fluorescent display, is proposed. A DC voltage source supplies the display voltage for the display and a heating current source for the heating device is constructed as a clock device (21, 19), pulsing the display voltage. In this way, the inherently low heating voltage can be derived from the higher display voltage, it being possible to save expensive, large-volume ballast elements and reduce the power loss. <IMAGE>

Description

The invention relates to a power supply device for the heating device of a heated display, in particular a fluorescent display, with a DC voltage source supplying the display voltage for the display and with a heating current source which is fed by a higher voltage than the required heating voltage.

The directly heated cathodes of fluorescent displays or fluorescent displays require a typical heating voltage of approx. 3 volts with a current of 70 to 120 mA depending on the number of filaments. In known power supply devices, this current is made available directly from the 220 V network, with conventional ballast elements for current limiting, such as foils, AC capacitors or ohmic resistors, being connected in series. A disadvantage of such a heating current source, in addition to the size and price of these ballasts, is the heating thereof and the power loss generated as a result. Capacitors of 1.5 MF or 20 W resistors are usually used for this. Another known possibility is to provide a separate power supply for the low heating voltage, which in turn has disadvantages in terms of size and cost.

An object of the present invention is to provide a power supply device for the heating device of a heated display according to the type mentioned at the outset, which significantly reduces the power loss at low cost and small size.

This object is achieved in that the heating current source is designed as a clock device clocking the display voltage.

• 1. Leistung N bei 3-Volt-Beheizung: N = Uh²/R.
• 2. Leistung bei getakteter Heizung: N = T . Ub²/R

In any case, a DC voltage source of approximately 24 volts is available as the display voltage for the display, from which the control signals for the display are formed. By clocking this display voltage, which is present anyway, it can be used for the power supply for the heating device, only one clock device being required, which is inexpensive with a small size is feasible. The power loss can be significantly reduced compared to a series resistor, as the following calculation example shows: With a heating voltage Uh = 3 V, a heating current at this voltage Ih = 100 mA, a display voltage Ub = 24 V, a pulse duty factor T and a resistance of the heating device R applies:

• 1. Power N with 3 volt heating: N = Uh² / R.
• 2. Power with clocked heating: N = T. Ub² / R

By equating the powers N, the duty cycle T = 1.56% results.

Durch den um den Faktor 8 reduzierten Heizstrom bei einer getakteten 24-V-Gleichspannung ergibt sich für ein Vorschaltelement ein Kondensator von nur noch ca. 0,18 MF anstelle 1,5 MF oder für den Ohmschen Widerstand eine Verlustleistung von nur noch ca. 2,5 W anstelle ca. 20 W.The average current Im is calculated as follows:

$\text{Im = T. Ub / R = T. Ub. Ih / Uh = Uh. 1h / Ub = 3/24. 100 = 12.5 mA}$

The heating current reduced by a factor of 8 with a clocked 24 V DC voltage results in a capacitor of only approx. 0.18 MF instead of 1.5 MF for a ballast or a power loss of only approx. 2 for the ohmic resistor , 5 W instead of approx. 20 W.

The measures listed in the subclaims are advantageous further developments and improvements the power supply device specified in claim 1 possible.

The clock device expediently has a clock frequency generator, the output signals of which have a duty cycle corresponding to the required heating power with regard to the display voltage. This enables simple adaptation to the required heating current when the display voltage is available.

The heating device can be acted upon directly by the output signals of the clock frequency generator if its output power is sufficient; on the other hand, the control input of a semiconductor switch can also be acted on by the output signals of the clock generator, the switching path of the semiconductor switch being connected in series with the heating device and with the DC voltage source supplying the display voltage. A clock generator with a very low output power can also be used here.

In the simplest case, the clock frequency generator can be an astable multivibrator, which can be designed as a separate component or can be contained in an electronic control unit for the display. This electronic control unit can of course also be a other type of clock frequency generator included.

To control the semiconductor switch, the display control pulses of the control unit for the display, which are present anyway, can be used, which are preferably applied to the control input of the semiconductor switch via a differentiating element. In this case, a separate output of the control unit for the heating can be omitted, and the heating control pulses are derived from the display control pulses which are present anyway, the required heating output being able to be set via the differentiating element. A microprocessor, which contains the clock frequency generator, also proves to be particularly advantageous. The required clock frequency and the required duty cycle are generated under program control.

The control unit containing the clock frequency generator can of course also be designed as a customer-specific, integrated circuit. In this case, the power of the clock frequency generator contained can be designed so high that the heating device can be acted upon directly by a corresponding output.

Fig. 1

ein erstes Ausführungsbeispiel mit einem separaten Taktfrequenzgenerator, der einen in Reihe zur Heizeinrichtung liegenden Halbleiterschalter steuert,

Fig. 2

ein zweites, ähnliches Ausführungsbeispiel, bei dem die Steuerimpulse für den Halbleiterschalter aus Anzeigesteuerimpulsen für das Display abgeleitet werden,

Fig. 3

ein drittes, ähnliches Ausführungsbeispiel, bei dem die Steuerimpulse für den Halbleiterschalter in einem Mikroprozessor erzeugt werden, und

Fig. 4

ein viertes Ausführungsbeispiel, bei dem direkte Steuerimpulse für die Heizeinrichtung in einem kundenspezifischen, integrierten Schaltkreis erzeugt werden.

Four embodiments of the invention are shown in the drawing and explained in more detail in the following description. Show it:

Fig. 1

1 shows a first exemplary embodiment with a separate clock frequency generator which controls a semiconductor switch located in series with the heating device,

Fig. 2

a second, similar embodiment in which the control pulses for the semiconductor switch are derived from display control pulses for the display,

Fig. 3

a third, similar embodiment in which the control pulses for the semiconductor switch are generated in a microprocessor, and

Fig. 4

a fourth embodiment in which direct control pulses for the heating device are generated in a customer-specific, integrated circuit.

In the first exemplary embodiment shown in FIG. 1, display control pulses for a display 10 (D) are generated in a microprocessor 11 (μP) and fed to the display 10 via five control lines 12-16. The term microprocessor is also intended to include, for example, a microcomputer. The microprocessor 10 is fed by a 24 volt DC voltage source, the DC voltage being supplied via two connections 17, 18. A DC voltage of 24 volts is usually required for the display control pulses.

The DC voltage present at the connections 17, 18 is applied to the series connection of the switching path of a semiconductor switch 19 with the heating device 20 of the display 10. This heating device usually consists of directly heated cathodes with a certain number of filaments. The output of an astable multivibrator 21 is connected via a resistor 22 to the control input of the semiconductor switch 19.

The astable multivibrator 21 is formed by a known circuit, which consists of the series connection of two inverters 23, 24, which are fed back via a capacitor 25. The first inverter 23 is additionally fed back via a resistor 26. Another known circuit for an astable multivibrator can of course also be used here.

Since the heating device 20 only requires a heating voltage of approximately 3 V, the DC voltage of 24 V cannot be applied directly. The semiconductor switch 19 is clocked by the astable multivibrator 21, so that clocked voltage pulses are supplied to the heating device 20 for heating it. The pulse duty factor is set so that the required heating output is achieved. From the calculation example given at the outset it follows that the current required is significantly lower compared to a continuous one Voltage application. Ballast resistors or ballast capacitors in a power pack, not shown, for generating the 24 volt DC voltage can therefore be dimensioned relatively small and with low power loss. Moreover, this circuit only needs a single voltage of 24 V to control the display 10 and to heat it. Depending on the display used, this voltage can of course also take on a different value.

The second exemplary embodiment shown in FIG. 2 has a similar structure. The same or equivalent components are provided with the same reference numerals and are not described again. In contrast to the first exemplary embodiment, the display control pulses of the control line 12 are used to control the semiconductor switch 19, which can be a transistor, for example. These display control pulses are generated at regular intervals in a conventional multiplex display, that is to say they have a specific frequency. These display control pulses are differentiated by an RC element 27 connected upstream of the control input of the semiconductor switch 19 as a differentiating element, so that the desired heating power or the desired duty cycle can be set via the semiconductor switch 19. A diode 28 connected in parallel to the base-emitter path serves as a protective diode.

The third exemplary embodiment shown in FIG. 3 again corresponds in part to the previous exemplary embodiments, so that the same or equivalent components are again provided with the same reference numerals and are not described again. In this exemplary embodiment, the clocked control voltage is generated internally in the microprocessor 11 and fed via the resistor 22 to the control input of the semiconductor switch 19. The clocked voltage is generated as a pulse train with a predetermined duty cycle via the program contained in the microprocessor 11.

In the fourth exemplary embodiment shown in FIG. 4, the semiconductor switch 19 is omitted, and instead of the microprocessor, a customer-specific control unit 29 designed as an integrated circuit is provided here. A clock frequency generator contained in this control unit 29 has such a high output power that the heating device 20 is connected directly between the output 30 of this control unit 29 and the connection 18. The clock frequency generator can be an astable multivibrator, for example.

Of course, it is also possible to vary the individual elements of the four exemplary embodiments with one another. For example, the heating device 20 can always be controlled directly when the corresponding one Output power is sufficient. This can also be the case, for example, with a control output of a microprocessor. Furthermore, it is possible, for example, that an external clock frequency generator, which is fed by the voltage at the connections 17, 18, acts directly on the heating device. Furthermore, the control transistor 19 can also be contained internally in a microprocessor or a customer-specific circuit. The required clock frequency can be formed in the microprocessor or in a customer-specific circuit by dividers present there.

Claims (9)

Power supply device for the heating device of a heated display, in particular a fluorescent display, with a direct voltage source supplying the display voltage for the display and with a heating current source which is fed by a higher voltage relative to the required heating voltage, characterized in that the heating current source is clocked as the display voltage Clock device (19,21,11,29) is formed. Power supply device according to Claim 1, characterized in that the clock device has a clock frequency generator (21), the output signals of which have a duty cycle corresponding to the required heating power with regard to the display voltage. Power supply device according to claim 2, characterized in that the heating device (20) is acted upon directly by the output signals of the clock frequency generator. Power supply device according to claim 2, characterized in that the control input of a semiconductor switch (19) is acted upon by the output signals of the clock generator (21), the switching path of the semiconductor. switch (19) is connected in series to the heating device (20) and to the DC voltage source supplying the display voltage. Power supply device according to claim 3 or 4, characterized in that the clock frequency generator (21) is an astable multivibrator. Power supply device according to one of Claims 3 to 5, characterized in that the clock frequency generator is contained in an electronic control unit (11, 29) for the display. Power supply device according to Claim 6, characterized in that the display control pulses from the control unit (11) are preferably applied to the control input of the semiconductor switch (19) via a differentiating element (27). Power supply device according to claim 6 or 7, characterized in that the control unit (11) containing the clock frequency generator is designed as a microprocessor. Power supply device according to Claim 6 or 7, characterized in that the control unit (29) containing the clock frequency generator is designed as a customer-specific, integrated circuit.

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