EP1071312A2 - PWM driving method - Google Patents

Abstract

The method involves using a current pulse whose current amplitude (IMAX) is greater than the maximum permissible amplitude (IG) for continuous operation, whereby the arithmetic mean over a period is equal to the maximum permissible current intensity for continuous operation. An Independent claim is also included for a PWM drive arrangement.

Description

The invention relates to a PWM control method and a control device for Influencing the brightness of luminous bodies according to the preamble of the claims 1 and 4.

With PWM control, the so-called pulse-width-modulated control of, for example, Lamps or display elements meant. The pulse width modulation is as is known both for the control of light elements, as well as electrical actuators used. Here, the electrical Actuation of a lighting element or an electrically operated one Elementes no longer on a permanent current, but it will be Current pulses or voltage pulses abandoned. Either the Pulse durations in which the current is applied, in their duration and thus in their pulse width can be varied, or it can be the time-out between the pulses in their duration and thus their breadth can be varied. In both cases this has one Influence on the lighting element or the electrical actuating element. On in this way, for example, dimming circuits can also be used Fluorescent lamps can be realized. To fluorescent lamps in their lighting effect To be able to dimmer, the current required for the discharge or the corresponding necessary voltage must be present. However, due to the temporary clocking or the introduction of a pulse pause reduces the integral of the power supplied. This effectively reduces the light output, even though the voltage required for the respective lighting or ignition process has its maximum value, ie its peak value maintains.

DE 197 11 885 A1 specifies a PWM control for decorative lamps, in which brightness changes are made using the PWM control become. The PWM control shown there is intended for fairy lights, etc.

EP 0 546 378 describes a PWM controller for LCD displays or LCD displays specified. Here, too, there is a change in the procedure outlined the brightness.

From JP 7183779 a PWM control is also specified for a display.

From DE 43 20 857 A1 a pulse width modulated control is connected used with discharge lamps in motor vehicles. The PWM control is supposed to do this the ignition process of said discharge lamps used in motor vehicles favor.

The first three documents from the prior art deal with the Problem of dimming, in particular DC-operated electronic Show. The PWM control mentioned in the fourth document is used for optimization the ignition process and the continuous operation of discharge lamps Motor vehicles.

Often, not only display elements are used in motor vehicles, but also Signal elements from electronic light sources such as light emitting diodes realized, but the achievable light outputs are limited.

The invention is therefore based on the object of a PWM control method and a to further develop the corresponding device of the generic type, that the illuminants or illuminants are used optimally in motor vehicles can.

The solution to the technical problem arises from the objects with the Features of claims 1 and 4. Further advantageous embodiments of the Invention result from the subclaims.

The essence of the invention with regard to the method is to be seen in that when actuated of illuminants or illuminants, especially of automotive signal lamps Achievement of a temporary maximum brightness of the peak current in pulsed PWM operation is a multiple of the maximum continuous current, the arithmetic Mean value is equal to the maximum permissible current for continuous operation. Thereby the lamps are temporarily operated in the overload area. Because of the quadratic relationship between current and power at ohmic Operations this leads to an increase in effective performance, although the respective mean current is equal. Especially with only temporarily active consumers the short-term increased power consumption is not critical and does not lead to Destruction of the lamps.

The process according to the invention can be used particularly advantageously in the case of light-emitting Use diode LEDs to bring their other benefits to bear, such as for example, lower heat loss and compact structure. Admittedly with LED's the light output only increases linearly with the current intensity, so that the total emitted Light output is constant, however, arises for the human viewer as a whole a lighter appearance due to the sluggishness of the human eye.

Their light output or the lighting effect and therefore the corresponding suitability as signal lamps in normal continuous operation is significantly lower than the luminosity of for example halogen-assisted light bulbs. With the invention However, it is possible to use signal lamps which consist of a plurality of LEDs exist in their light output or in the physiological To significantly increase light perception. This is achieved in that the currents causing light-emitting effect through said LEDs and signal lamps formed therefrom are a multiple of what is usually manageable Continuous current is. In order not to destroy said LEDs, however, the said peak current surge pulsed, d. H. controlled pulsed, in PWM mode performed. For example, this could mean that LEDs with a maximum continuous current design of 30 mA pulsed with the PWM operation Peak currents of 90 mA can be operated. Through the controlled introduction of Viewed over a period of time, pulse pauses result in an average current, however with regard to the pulse times and the set pulse pause times on average again does not exceed the maximum continuous current. In other words, this means that if the current is represented as a function of time, the integral under the PWM clock curve is equal to the integral of the continuous current over the total operating time. In order to the components, i.e. the light-emitting diodes, are protected, while the perceptible Luminous effect is multiplied.

It is provided in a further advantageous embodiment that for the duration of Actuation of the LEDs, the PWM control is clocked so that the Pulse frequency is greater than or equal to the stroboscope frequency of 50 Hz, at which over human perception creates an apparent permanent light. The human The eye detects the light measured at its tip line, the clocks in their Frequency are then selected so that the pulse pause times are no longer perceived become. In this case, the physiological perception of the light effect is through exploited the human eye. There is no integral recording here of a lighting condition, but the human eye registers on this Way the light output peaks.

In a further advantageous embodiment of the method according to the invention provided that the available on-board voltage is determined in the motor vehicle, and that On-board voltage fluctuations are regulated in this way when the signal lights are actuated be that constant maximum light output is generated. Here should simply in a further advantageous embodiment, the lack of a possibly variable or fluctuating on-board voltage can be compensated. This is done at lower vehicle electrical system voltages and thus lower currents for the Current pulses extend the pulse time accordingly.

It is necessary that the current can be measured at all times in order to one as possible, as already described above, in its output or its light output To ensure constant control of the signal lamps.

In a preferred embodiment, the illuminants or illuminants are as Signal lights designed in a motor vehicle, such as brake lights, Additional brake lights or reversing lights, as these are only briefly high Luminance levels are required. Another area of application are Direction indicators.

To generate the necessary peak currents in the vehicle electrical system, either the On-board electrical system voltage can be designed to be higher, or at least a partial on-board electrical system include higher voltages. Another option is to use it of voltage and current multipliers, built up electrically or electronically are, such as a DC / DC converter.

The invention is shown schematically in the drawing and is described in more detail below described.

Figur 1:

PWM-Betrieb zur Ansteuerung von Leuchtdioden mit sowohl variabler Pulsein- als auch Pulsauszeit.

Figur 2:

Prinzipieller Aufbau der Einrichtung.

It shows:

Figure 1:

PWM operation for controlling LEDs with both variable pulse on and pulse off times.

Figure 2:

Basic structure of the facility.

Figure 1 shows in its schematic representation the cycle used here in PWM operation. Here, a boundary line is shown, which represents the continuous current I _G. A multiple of the maximum continuous current I _G for corresponding pulse times is generated on the ordinate in pulse width mode. The pulse times as well as the pulse times are set so that, on the one hand, the physiological impression of a continuous light on a light electrode is created and, on the other hand, the integral of both signal runs, i.e. the areas under the constant current signal is equal to the integral area under the PWM curve. This ensures that the average current is not above the maximum continuous current I _G. However, a peak current I _{MAX is} generated for the short cycle times, which is a multiple and thus also generates a multiple of light emission at the light electrode. The pulse time-outs or the frequency of the clocking ultimately brought about by this is selected such that a continuous light of increased intensity arises in the physiological perception of the human eye. The light effect generated in this way is far above the perceived light effect with a continuous current, as represented by the straight line at I _G. In both cases, however, the same power is given to the LED. However, in the latter case, the human perceived lighting effect is significantly lower. Preferably I. MAX = 1.5-3 x I G chosen.

Figure 2 shows a basic representation of the device according to the invention. Here the signal light 1 shown consists of light-emitting diodes 10 LEDs. The this acting voltage unit 2 is PWM controlled and delivers the current curve shown in Figure 1 in the clocked manner shown there. At appropriate setting of maximum exploitable lighting effect comes to a appropriately regulated influence on both the pulse times and the Pulse timeouts on. The pulse timeouts ultimately reflect the frequency below which a physiological impression of continuous light arises and the pulse times result in the maximum adjustable peak currents, so that the connection between pulse input and Pulse time-out, in addition, the current integral to that of the continuous current limit.

It is also necessary here for a current measurement to be carried out using appropriate means 3 is carried out in the current path of the light-emitting diode, so that here a corresponding Control intervention to determine the pulse on and pulse off times for the each case can be calculated. For the determination of suitable frequencies in order To create a permanent light in his perception, frequencies are required that are equal to or greater than 50 Hz. For example, an otherwise permissible However, continuous current of 30 mA for the corresponding light-emitting diode is also quite possible Peak currents on the order of 90 mA are allowed, leading to the said significant increase in the lighting effect leads.

Thus, the control, for example an additional brake light, is not carried out directly via the actuating element 4. When actuated, the Controlled voltage unit with integrated PWM device and then over only the signal element with the diodes 10.

Claims (7)

PWM control method, for influencing the brightness of illuminants or illuminants,
characterized in that
the current strength I _{MAX of} the current pulses is greater than the maximum permissible current strength I _G for continuous operation, the arithmetic mean over a period being equal to the maximum permitted current strength I _G for continuous operation. PWM control method according to claim 1, characterized in that the Pulse frequency is greater than or equal to 50 Hz. PWM control method according to claim 1 or 2, characterized in that the available current strength of the current pulses is detected, lower ones Current strengths can be compensated by extending the pulse times. PWM control device for influencing the brightness of luminous elements or illuminants, comprising a voltage or current source for generating current pulses, characterized in that the current strength I _{MAX of} the current pulses is greater than the maximum permissible current strength I _G for continuous operation, the arithmetic mean being the same the maximum permissible current I _G for continuous operation. PWM control device according to claim 4, characterized in that the Pulse times are changeable depending on the detected current. PWM control device according to claim 4 or 5, characterized in that the lamps are designed as light-emitting diodes (10). PWM control device according to one of claims 4-6, characterized characterized in that the illuminants or illuminants as signal lights in a motor vehicle are formed.

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