DE3742245A1 - MIXED BULB / FLUORESCENT LIGHT SOURCE FOR LIQUID CRYSTAL DISPLAYS - Google Patents

Abstract

A light source (9) for a transmissive liquid crystal display panel (1) consists of an array of alternate fluorescent (12) and incandescent (13) light elements. The incandescent light elements provide light for the display at low temperatures while simultaneously acting as a radiant heat source for the adjacent fluorescent elements to permit the fluorescent light elements to operate at ambient temperature at which they normally do not emit light or emit light at very low levels. <IMAGE>

Description

Flat panel liquid crystal displays typically include a liquid crystal panel with a light source for illuminating the liquid crystal display mounted behind the panel. In many cases, the liquid crystal display must be viewed under ambient conditions, and for example, a liquid crystal display used in the cockpit of an aircraft must be visible at ambient light intensities, which can reach up to 34 262.59 cd / m ² (10,000 foot-lam bert) could be. Under these ambient conditions, the illuminance for the display must be 6852.518 cd / m ² (2000 feet-lambert) or greater. The light source for the display must therefore be able to supply this illuminance and must also be able to do so at extremely low temperatures, ie at temperatures down to -50 ° to -55 ° C.

It is the operation at these extremely low temperatures that poses problems with spectral light sources that are otherwise the main contenders for the application. That is, fluorescent lamps that are capable of delivering high-intensity light outputs [of over 6852,518 cd / m ² (2000 foot-lambert) at 40 ° to 50 ° C] work very poorly at low temperatures. In fact, fluorescent light sources are essentially ineffective around -50 ° C. Incandescent light sources on the other hand are insensitive to temperature, ie the light output is essentially constant over a range of temperatures from -60 ° C to + 70 ° to 75 ° C. Although incandescent light sources are effective at low temperatures, their output power is quite low [around 2055.7544 to 2398.3813 cd / m ² ) (600 to 700 foot-lambert)] and their performance in cd / m ² · W (foot- lambert / watt) compared to fluorescent lights quite low.

In the course of investigations into the present inven were found to have a high light output performance and a highly efficient operation low temperatures by means of a mixed light system, in which a variety of incandescent and fluorescent lamps in Neighborhood to each other in a parallel arrangement are arranged, can be achieved. At low temperatures The light bulb elements provide light for the display and them also act as a source of heat radiation for the neighboring ones Fluorescent lamps. The heat effect of the incandescent lamps increases the Temperature in the immediate vicinity of the fluorescence enough to match the fluorescent lamps a working and the formation of an effective light output enable performance even when the ambient temperature, in which the light source and the flat fluorescent plate work at or below the temperatures at which cher the fluorescent lamps are either ineffective or very have low output powers.

It is therefore a primary object of the invention to provide a light source for creating a liquid crystal display which is capable is, at very low temperatures with high performance ability to work with high light output.

Another object of the invention is a liquid to create a crystal display system containing a mix light source, which by its nature both incandescent Includes fluorescent elements to take advantage of the be most operating features to operate from both.

Yet another object of the invention is to provide one low temperature operational mixed incandescent / fluo to create resence light source.

Other objects and advantages of the invention will be apparent from the following description.

The aims and advantages of the invention are in one arrangement realized in which the light source for a river sig crystal display panel from a variety of elongated Fluorescent and incandescent lights exist on a support plate are mounted in a parallel arrangement, whereby Fluorescent and incandescent lamps alternately in the neighborhood are mounted to each other. That of every light bulb in operation radiation energy emitted at low temperatures acts as a heat source for the fluorescent lamps on each side of the Light bulb. As a result, the temperature increases in the immediate neighborhood of any fluorescent lamp in the we considerable about the ambient temperature, which makes it the Fluorescent lamps is enabled at ambient temperatures to work where they are normally ineffective or where they emit very little light.  

The new features that are characteristic of this invention are explained in more detail in the claims. The invention itself, along with other goals and advantages The same can best be done by the following description exercise in connection with the drawings in which

Fig. 1 is a partial perspective interior view of a display plate arrangement, including the mixed fluorescent light / incandescent light source means;

Fig. 2 is a graphical representation of the light emission properties of fluorescent and incandescent light sources as a function of temperature;

Fig. 3 is a graphical representation of the light emission properties of the mixed fluorescent light / incandescent light source.

As is known, liquid crystal displays typically exist from two transparent glass substrates, separated by one Sealing agent for delimiting a cavity in which a liquid crystal solution is held. The inner waiters the display elements have surfaces of the transparent glass plates elements in the form of signs, symbols or fig endings.

Therefore there is a metallic backing on the inner top surface applied by a substrate and individual transpa annuity conductive electrodes (arranged in any ge desired form, such as in the form of lines and Gaps) are on the inner surface of the other substrate appropriate. The transparent electrodes are made from one transparent metal such as indium tin oxide (ITO) or the like.

Fig. 1 shows a liquid crystal display element mounted in a housing 2. The housing 2 has an opening 3 in which an observation window 4 is mounted in order to enable the display to be viewed. At the lower end of the housing is a control plate 6 ("driver electronic panel") which carries the row and column driver electronics for selective current supply to the individual pixels (picture elements) of a matrix liquid crystal display. Arranged immediately behind the liquid crystal plate is a scattering element 7 , which receives light from the mixed light source 9 arranged directly on its rear side. Behind the light source 9 , a printed circuit board 10 is mounted on a bracket 11 . The printed switching display 10 carries the power supply and other Energiezufüh approximately.

The mixed fluorescent / incandescent light source 9 consists of a plurality of fluorescent lamps 12 , mounted horizontally on the plate 10 . Incandescent lamps 13 are arranged between the fluorescent lamps so that the source 9 consists of an alternating arrangement of fluorescent and incandescent lamps. The fluorescent and incandescent lamps are arranged so that they are in a heat exchange relationship with each other.

That is, the radiation generator emitted by the incandescent lamps gie increases the temperature in the immediate aftermath the fluorescent lamps, so that the fluorescent lamp pen temperature significantly higher than the ambient temperature is inside the case, which makes it the fluorescent lamp is enabled to work more effectively than the environment temperature would normally allow.

At extremely low temperatures, i.e. H. -50 ° C or below, the light bulbs are the main light source for the liquid crystal  stall display. At the same time it heats up from the glow radiation energy emitted by the fluorescent lamps and increases their output power. In a real short time interval, 10 minutes or less, increases that at one turn operating temperature of -50 ° C operated mixing system the tempe temperature of the fluorescent lamp surfaces by approximately 40 ° C above the ambient temperature, and thereby enables that whose light output increases significantly, even though the ambient temperature remains extremely low.

FIG. 2 graphically illustrates the daylight delivered ( "photopic output") from fluorescent and incandescent lamps as a function of temperature. Therefore, the day light output is shown in Fig. 2 applied in cd / m (foot-lambert) on a logarithmic scale along the ordinate and the temperature in ° C linearly along the Radofs se.

Curve 20 shows the daylight emission as a function of the temperature of a fluorescent lamp and curve 21 is the daylight emission of an incandescent lamp as a function of temperature. The data plotted as curve 20 in FIG. 2 represent the daylight emissions of a fluorescent lamp operated at 38 volts, 0.70 A, ie a power supplied of 21.8 W. Curve 21 represents the light output of an incandescent lamp operated at 12.1 V and 1.55, ie an input power of 18.8 W. It can be found from curve 20 who below that the light output of the fluorescent lamp is extremely low at -20 ° C by 137.05036 cd / m ² (40 foot-lambert) and at -50 ° C by 34.26259 cd / m ² (10 foot lambert) [less than 1.7131295 cd / m ² · W (0.5 ft lambert / watt)]. Under the good environmental conditions, which are not uncommon in aircraft operations where an aircraft can be parked overnight in extreme cold, a light source consisting of fluorescent lamps will produce a very small light output.

The light emission of the fluorescent lamp never reaches 10 278.777 to 13 705.036 cd / m ² (3000 to 4000 footlambert) until the ambient temperature is approximately 20 ° to 60 ° C. Therefore, the light output of a fluorescent lamp in its optimal operating condition is 40 ° to 60 ° C by 13 705.036 cd / m² (4000 foot-lambert) or approximately 685.2518 cd / m ² · W (200 foot-lambert / watt) .

The light output of an incandescent lamp, as explained by Kur ve 21 , is essentially constant in temperature. However, the efficiency of an incandescent lamp is relatively low rig compared to the optimal efficiency of a fluorescent lamp. That is, the light output of an incandescent lamp with an input of 19 watts is approximately 2055.7554 cd / m ² (600 foot-lambert) or approximately 109.64028 cd / m ² · W (32 lambert watt); an efficiency that is almost an order of magnitude smaller than that of the fluorescent lamp with optimal efficiency.

Fig. 3, the daylight-response ( "photopic response") explains the mixed incandescent light / fluorescent light source of the present invention as a function of time and shows the effect of radiant energy from the bulb to a fluorescent lamp with a anfäng integrated energy supply at an ambient temperature of - 55 ° C. As indicated in more detail below, the actual lamp temperature rises from -55 ° C to approximately + 20 ° C within 10 minutes, which means that the daylight emission of the fluorescent lamp increases in principle from zero to approximately 5482.0144 cd / m ² (1600 foot-lambert) is increased. In Fig. 3, the light emitting days in cd / m ² (foot-lambert) along the ordinate and the time in minutes is plotted along the abscissa. Curve 23 shows the total light output of the mixed lighting system (fluorescent plus incandescent light source). The energy supplied to the incandescent and fluorescent lamps is the same as that described for the units in connection with Fig. 2; that is, a 21.8 watt input to the fluorescent lamp and an 18.8 watt input to the incandescent lamp.

The unit was initially stored in a tenny oven at -55 ° C for 1 hour before starting the experiment. As soon as energy was initially supplied to the lamps, time equal to 0, the ambient temperature measured in the housing was -53 ° C., and the light output was approximately 2364.1187 cd / m ² (690 foot-lambert). The initial light output is therefore essentially the output of the incandescent lamp, since (as shown in Fig. 2) the light output of the incandescent lamp is approximately 2329.8561 cd / m ² (680 foot-lambert) over the entire temperature range. As soon as energy is supplied, the light output of the mixing system increases rapidly over time. 10 minutes later the ambient temperature had risen to -19 ° C. However, the light output is above 7880.3957 cd / m ² (2300 foot-lambert). Since approximately 2329.8561 cd / m ² (680 lambert) represent a constant light output from the incandescent lamps, the remaining light output of 5482.0144 cd / m ² (1600 foot-lambert) represents the light output of the fluorescent lamps.

It can be seen from curve 20 of FIG. 2 that the light output of the fluorescent lamp increases to approximately 5482.0144 cd / m ² (1600 foot-lambert) at + 20 ° C. It is therefore evident that the incandescent lamps increase the lamp surface temperature approximately 40 ° C higher than the ambient temperature and allow the fluorescent lamps to operate at much higher levels of efficiency and light output than would be possible at the given ambient temperatures.

It is therefore evident that mixed fluorescence Light / incandescent light source very effective at extremely low temperatures instruments works; d. H. Temperatures at which the high effective fluorescent light sources normally either un are effective or with a very low light output work. It is therefore clearly evident that such a light source is capable of at extremely low temperatures work with high light outputs, and with the high efficiency of fluorescent light sources, the are usually able to work effectively and effectively to be at these temperatures.

Although the present invention in connection with a preferred embodiment of the same has been described the invention is not to be limited thereby, since other Mo differences in the equipment used can and still fall within the scope of the invention. The claims are intended to be all such modifications cations of the invention include and fall under the invention.

All patents cited in this specification Writings and publications are expressly referenced and the disclosure content of all of these publications by this reference in full in the integrated registration.

Claims (9)

1. Liquid crystal display system containing

• (a) a liquid crystal display,
• (b) a light source located between the display, where this light source:
  • 1. vehicle aids,
  • 2. contains at least one fluorescent light element and one incandescent light element mounted on the carrier,
  • 3. wherein the incandescent light element is arranged to act as heat sources for the fluorescent element in order to raise the temperature of the fluorescent element above the ambient temperature, as a result of which the light output from the fluorescent element is greater than it would be at ambient temperature.

2. Liquid crystal display system according to claim 1, there characterized in that the light source a variety of fluorescent and incandescent elements ten includes. 3. Liquid crystal display system according to claim 2, there  characterized in that the fluores zenzlicht- and incandescent light elements in a parallel arrangement are switched on. 4. Liquid crystal display system according to claim 3, there characterized in that the parallel Arrangement of alternating fluorescent light and incandescent light elements includes. 5. Mixed fluorescent light and incandescent light source, ent

• (a) vehicle auxiliaries,
• (b) at least one fluorescent light element and one incandescent light element mounted on the carrier,
• (c) the incandescent light element being arranged to act as a heat source for the fluorescent element in order to raise the temperature of the fluorescent element above the ambient temperature.

6. Mixed light source according to claim 5, characterized characterized in that the light elements in Wär exchange relationship are mounted and the fluorescent cell ment exposed to heat radiation from the glow element is. 7. Mixed light source according to claim 5, characterized characterized that the light source is a lot number of fluorescent and incandescent elements. 8. Mixed light source according to claim 7, characterized characterized that the multitude of elements are mounted in a parallel arrangement.   9. Mixed light source according to claim 8, characterized characterized in that the parallel arrangement includes alternating fluorescent and glow elements.