DE19926980A1 - Enhance the luminance of long afterglow and / or fluorescent surfaces - Google Patents

Abstract

The present invention relates to a light-emitting, long-afterglow and / or fluorescent object, its use as a security marking and further to a method for increasing the luminance of a long-afterglow and / or fluorescent object.

Description

The present invention relates to long-afterglow and / or fluorescent Objects, predominantly long afterglow and / or fluorescent surfaces, Layers or coatings with high luminance and directional light broadcast, a method of increasing the luminance of a langnach luminous and / or fluorescent object and the use of a The subject of the invention as a security marker.

Long afterglow and / or fluorescent safety markings are used to identify escape routes and escape routes as well as to identify safety-relevant devices on escape routes and escape routes so that they can still be recognized even in the event of light failure. The phosphorescence luminance and the size of the phosphorescent surface are decisive for the perceptibility of long afterglow and / or fluorescent security markings in the event of sudden power failure and absolute darkness. More recently, afterglow and / or fluorescent security markings, which are used in the form of signs, plates, foils and molded parts, have become much more persistent and / or fluorescent security markings due to more recent developments both on the part of the phosphorescent phosphors and in the production and design Measure used in various areas as classic emergency lighting systems. Long afterglow and / or fluorescent security markings can be used much more flexibly than classic emergency lighting systems, both in the general working environment and in public and commercial facilities, buildings, paths, stairs, train stations, on ships and the like. with a high visitor frequency or visitor presence. As already indicated, in addition to the size of the area, the luminance is particularly decisive for the recognizability of a long-afterglow and / or fluorescent safety product. The luminance is influenced by the quality of the phosphor, by the amount of phosphor occupied, expressed in g / m ² , by the type and color of the substrate, the transparency of the medium in which the phosphor is embedded, such as, for example, a lacquer or a polymer, and from processing. In addition, the luminance in the application naturally depends very much on the existing ambient lighting, ie on the type of light and the amount of light. While white and cool white light from fluorescent lamps charges the afterglow and / or fluorescent products very quickly, warm white or red light is suitable to a much lesser extent. The terms "cool white" and "warm white" are used here according to the standard values for color coordinates and color temperature of the American National Standards Institute (standard C78.376). Warm white or red light is emitted essentially by incandescent or fluorescent lamps of the color "warm tone". Under conditions of use, ie on escape or rescue routes, in commercial, industrial and public facilities, it is to be expected that the existing lighting system contains all types of light and at the same time it is to be expected that the level of lighting is very low. It is quite realistic to assume that an illumination level of 10 Lx ("Lx" corresponds to a unit of illuminance as the quotient of luminous flux and emitting area) and less is found in hotels or in stairwells.

In order to be able to effectively use long-afterglow and / or fluorescent markings under such conditions, the long-after-glow and / or fluorescent markings must have a high phosphorescence loading capacity and also a high luminance when the light emission decays. It should be noted here in particular that the loading of the surface of a marking with a phosphorescent pigment, which is given in g / m ² , also determines the production costs of a long-afterglow and / or fluorescent marking product. The higher the loading of the corresponding surface with a selected phosphorescent pigment, the higher the manufacturing costs of the mark in question.

It is an object of the present invention to improve the phosphorescence or Fluorescence luminance of long afterglow and / or fluorescent Markings, especially of security markings, for the same Fluorescent occupancy and other similar conditions significantly increase so that the perceptibility of these markings increases significantly and thus the person who is fleeing in dangerous situations is the saving way is signaled even better and more reliably.

This object is achieved by an object according to claim 1 and a method ren solved according to claim 10. Further design options and Advantages are specified in the subclaims.

While the luminance of a long-afterglow and / or fluorescent marking is independent of the angle ϑ between the surface normal and the direction of observation and always has a constant value B ₀ , the luminous intensity dI varies with ϑ and is proportional to cosϑ in the direction ϑ, because from the Seen in direction ϑ, the emitting area dA of the marking only has the apparent area dA '= dA cosϑ. This proportionality to cosϑ is called the Lambert law:

dI (ϑ) = B ₀ dA '= B ₀ dA cosϑ (I)

B ₀ = dI (ϑ) / dA cosϑ (II)

The present invention now provides a long range according to claim 1 luminous and / or fluorescent object ready, at least one long afterglow or fluorescent phosphor or a mixture of has two or more of them and emits light directed, d. H. the light will in a preferred direction, for example perpendicular to the surface of the emitted light-emitting object.

In a preferred embodiment of the invention, the long-afterglow and / or fluorescent object is provided with an interference filter. With the help of a suitable interference filter, it is possible to achieve light bundling in a preferred direction perpendicular to the light-emitting surface and thus initially to significantly increase the light intensity dI (ϑ) in this direction ϑ and thus also the luminance B ₀ in this direction.

With the conventional long-afterglow and / or fluorescent security markings, the light is emitted at angles between 0 ° and 180 ° to the emitting surface of the marking. By arranging an interference filter appropriately on the radiating surface of the marking, the luminance orthogonal to the surface can be increased compared to conventional long-afterglow and / or fluorescent security markings. With an appropriate arrangement of the interference filter on the emitting surface of the marking, the angle ϑ under which light is emitted can be restricted to a smaller angular range and at the same time light that would otherwise have been emitted outside this angular range can be reflected in this restricted angular range. The luminance B _{0 of} the surface is thus significantly increased in this preferred direction ϑ.

There are no restrictions on the type of interference filter that can be used kungen. In a preferred embodiment, the interference filter is in shape a film in front that is applied to the surface of the light-emitting object is brought. This embodiment is advantageous in terms of its manufacture, because the application of a film is relatively quick and easy. The Interference filter can also consist of a combination of several foils consist.

Alternatively, the interference filter can also be applied to a suitable substrate vapor-deposited layer or correspond to several vapor-deposited layers.

Another alternative is an embodiment in which the carrier layer itself represents an interference filter if e.g. B. the phosphor by means of a sieve printed on the back of the interference foil.

The long-afterglow and / or fluorescent object according to the invention has at least one phosphor. Depending on the chosen phosphor, the Duration of afterglow or fluorescence of different lengths.

Examples include:  

Fluorescent materials, such as those found in Ullmann's encyclopedia of technology Chemie, 4th edition, volume 16, pp. 179 ff. (1975) are described, e.g. B. such Base of sulfides, such as. B. CaS: Bi, CaSrS: Bi, ZnS: Cu and ZnCdS: Cu.

Phosphors based on alkaline earth aluminates, such as. B. with Europium or with Lead activated alkaline earth metal aluminates, the alkaline earth metal strontium or is a mixture of strontium and calcium, e.g. B. in EP-A 0 094 132 and US 3,294,699 (Sr aluminate / Europium), also by Europium activated alkaline earth aluminates, with barium and strontium as Alkaline earth metals, as described in DE-A 18 11 732;

Phosphors comprising a matrix of the formula M _1-x Al ₂ O _4-x , where M is at least one metal selected from Ca, Sr and Ba, and X is an integer other than 0, and the matrix Eu as activator and as co- Activator contains at least one of La, Ce, Pr, Nd, Sm, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Mn, Sn and Bi, as described in EP-A 0 710 709;

Phosphors comprising a composition MO ~ a (Al _1-b B _b ) ₂ O ₃ : cR, in which 0.5 ≦ a ≦ 10.0, 0.0001 ≦ b ≦ 0.5 and 0.0001 ≦ c ≦ 0, 2, MO represents at least one divalent metal oxide selected from MgO, CaO, SrO and ZnO, and R represents Eu and at least one additional rare earth element, as described in DE-A 195 21 119;
Rare earth metal doped alkaline earth aluminates, as described in EP-A 0 710 709 and DE-A 195 21 119;
Luminescent materials comprising a matrix with the formal MAl ₂ O ₄ , where M is calcium, strontium or barium and the matrix europium as activator and as co-activator at least one of lanthanum, cerium, preseodymium, neodymium, samarium, gadolinium, dysprosium, holmium, Erbium, thulium, ytterbium, lutetium, tin and bismuth contains, as described in EP-B 0 622 440; Europium activated ternary metal oxides containing SrO or BaO or mixtures thereof, Al ₂ O ₃ or a mixture of Al ₂ O ₃ and Ga ₂ O ₃ and ZnO or MgO, as described in US Pat. No. 4,216,408;
and phosphors containing at least one metal oxide selected from MgO, CaO, SrO and ZnO, and as activator Eu ²⁺ and at least one additional rare earth element selected from Pr, Nd, Dy and Tm, preferably Dy, as described in US Pat. No. 5,376,303.

Phosphors based on an alkaline earth aluminate, in particular those in EP-B 0 622 440, EP-A 0 710 709, DE-A 195 21 119 and the phosphors described in US Pat. No. 5,376,303.

Phosphors based on SrAl ₂ O ₄ : Eu, Dy or ZnS: Cu phosphors are preferably used here. Examples include those commercially available under the brand name "LUMILUX® Long Afterglow Pigments", namely LUMILUX® Green SN-CR, LUMILUX® Green SN-C, LUMILUX® Green SN-FOG, LUMILUX® Green SN-F2, LUMILUX® Green SN -S, LUMILUX® GreenN 5, LUMILUX® Green N-PM, LUMILUX® Green NN, LUMILUX® Green N2, LUMILUX® MB Green SN, LUMILUX® Green NM 33 or those known under the name "LUMILUX® Effect Pigments "are available, for example LUMILUX® Effect Blue N, LUMILUX® Blue-Green SN, LUMILUX® Blue-Green SN-F, LUMILUX® Effect Green N, LUMILUX® Effect Green NL, LUMILUX® Effect Green NE, LUMILUX® Effect Green NF, LUMILUX ® Effect Green N-FG, LUMILUX® Effect Green N-FF, LUMILUX® Effect Sipi F Yellow SN, LUMILUX® Effect Sipi Yellow, LUMILUX® Effect Sipi Red, LUMILUX® Effect Red N 100, LUMILUX® Effect Red N 40.

But all other phosphors can also be used, such as UV stimulable, i.e. fluorescent, phosphors. These include, for example Lamp phosphors that are commercially available under the name "LUMILUX® Q- Pigments "are available, namely under the brand names LUMILUX® Red QYV, LUMILUX® Red QYO, LUMILUX® Red QG, LUMILUX® Blue QCW. Also inorganic coding pigments with the brand name "LUMILUX® C pigments" can be used. These are, for example under the brand names LUMILUX® White CD 128, LUMILUX® Blue CD 164, LUMILUX® Blue CD 165, LUMILUX® Blue CD 162, LUMILUX® Blue CD 144, LUMILUX® Green CD 140, LUMILUX® Green CD 112, LUMILUX® Green CD 111, LUMILUX® Green CD 1116, LUMILUX® Green CD 117, LUMILUX® Green CD 145, LUMILUX® Green CD 163, LUMILUX® Green CD 166, LUMILUX® Turquoise CD 167, LUMILUX® Red CD 110, LUMILUX® Yellow Orange CD 135, LUMILUX® Yellow Orange CD 130, LUMILUX® Red CD 168, LUMILUX® Red CD 120, LUMILUX® Red CD 141, LUMILUX® Red CD 105, LUMILUX® Red CD 106.

The amount of the phosphor used is not particularly limited. The assignment for ZnS phosphors is preferably in a range from 300 g / m ² to 400 g / m ² , for phosphors based on SrAl ₂ O ₄ in a range from 30 g / m ² to 300 g / m ² .

The afterglow after removing the excitation source can be dark adapted eye should preferably be recognizable after 20 hours.  

In a further preferred embodiment, the object according to the invention has at least the following elements:

• a) a carrier layer,
• b) at least one, arranged after the carrier layer luminous and / or fluorescent layer,
• c) at least one above the long afterglow and / or fluorescent layer arranged interference filter.

In a preferred embodiment, the interference filter is for vertical and Green light radiated almost perpendicular to the filter is transparent, while light, that falls on the interference filter at a different angle from that Interference filter is reflected. It can also be a non-green phosphor be used. The light that is from the at least one over the Carrier layer arranged long afterglow and / or fluorescent Layer is emitted in the direction of the interference filter, only passes the filter then when it is at an angle of 90 ° or just a little different Filter hits. Rays of light shining on the at a much smaller angle Interference filters hit, are reflected by the filter and fall again back to the long afterglow and / or fluorescent layer. For the reflected light rays there are several options. You can for example absorbed by a phosphor particle and by this Fluorescent particles are later emitted again or the light rays meet a second crystal and are directed directly from it towards the Interference filter reflected. Ultimately, however, multiple reflections can also occur the light rays within the long afterglow and / or fluorescent Shift come. This therefore results in that of the interference filter back-reflected light rays after renewed absorption within the afterglow and / or fluorescent layer or after the renewed Reflection within this layer allows you to go back towards  Interference filter to be emitted. Thus the luminance becomes vertical to the interference filter and at the same time the one emitted laterally Light intensity reduced. With the help of the interference filter, the Luminance observable perpendicular to the interference filter to the disadvantage of the Luminance observable to the side of the interference filter increased.

In a preferred embodiment of the invention, the invention Subject to other layers besides the layers listed above, for example a UV protective layer or a protective layer for reduction flammability. It is preferably located between the carrier layer and the phosphor layer is a diffusely reflective layer. This will ensures that none of the afterglow and / or fluorescent Layer emitted in the direction opposite to the direction of the interference filter Light beam is lost, but at least back into the long afterglow or fluorescent layer is reflected back and thus has the possibility be it through direct passage through the afterglow and / or fluorescent layer or by repeated absorption with subsequent Re-emission or by one or more reflections within the long afterglow and / or fluorescent layer, in the direction of Interference filter to be emitted.

In a further preferred embodiment of the invention, the Backing layer itself made of a diffusely reflective, white material. A coated metal sheet or a metal foil is preferred here used. Aluminum is particularly preferred, but also other metals can be used. Furthermore, the carrier layer, preferably the metal sheet, have a further layer comprising an enamel. Enamel serves as Embedding material for the phosphor particles.  

The long afterglow and / or fluorescent layer has, as already indicated, at least one phosphorescent phosphor.

In a further embodiment of the invention, the carrier is made of glass, Quartz glass or a transparent polymer and the fluorescent layer includes a UV phosphor. In this case UV radiation is preferred from behind, d. H. through the transparent support on the fluorescent layer irradiated.

In another preferred embodiment of the object according to the invention, the long-afterglow and / or fluorescent layer containing the at least one phosphor has other substances in addition to the phosphorescent or fluorescent phosphor, such as binders or fillers. For example, polymers such as PVC, white pigments such as TiO ₂ , UV absorbers, flame retardants and / or screen printing binders are used here.

Furthermore, the invention also relates to the use of the invention Item as a security marker. The long afterglow or the Fluorescence and the increased luminance in a preferred direction of the The object of the invention offers considerable advantages in the marking of escape routes to make them recognizable even in the event of light failure.

With regard to the shape of the object according to the invention or the invention There are no restrictions in accordance with the security marking, i. H. she can for example in the form of signs with different thickness and with different edge lengths. In addition, a Security marking according to the invention or an inventive  Subject still additional prints with a non-phosphorescent Color included.

Furthermore, the invention also relates to a method for increasing the luminance of a long-afterglow and / or fluorescent object, the method comprising at least the following step:

• a) arranging at least one interference filter on the long afterglow and / or fluorescent article.

The invention will now be explained in more detail with reference to the following examples in conjunction with FIGS. 1 to 3 and Table 1. Show it:

Fig. 1 shows a schematic structure of an embodiment of an article according to the invention;

Fig. 2 plot of the afterglow density in mcd / m ² of Examples 1 (solid line) and 2 (dashed line) against the time in minutes;

Fig. 3 plot of the afterglow density in mcd / m ² of Examples 3 (solid line) and 4 (dashed line) against the time in minutes.

Fig. 1 shows the schematic structure of an embodiment of an object according to the invention or a security marking according to the invention. The object G according to the invention has three layers A, B and C in the present embodiment. Layer A represents the carrier layer. As mentioned above, this carrier layer A consists in a preferred embodiment of a diffusely reflecting material. This can prevent any light beam emitted from or passing through the long afterglow and / or fluorescent layer B from being absorbed in the carrier layer A and thus being lost. On this carrier layer A there is applied a layer B which has a long afterglow and / or fluorescence and has fluorescent crystals B 'and which emits light in the direction of the interference filter C. The light that strikes the interference filter at an angle of 90 ° or deviates only slightly from it can pass through the interference filter, such as the light beams 2 to 4 shown here. Light rays that hit the interference filter at a much smaller angle than 90 °, such as rays 6 and 7, on the other hand, are reflected on the interference filter, so that they hit the long-afterglow and / or fluorescent layer B again. For these reflected light beams there are several options with regard to their further course. On the one hand, they can be absorbed by a phosphor particle B 'and later emitted again by the latter, or they are reflected directly by a second phosphor crystal 8 ' in the direction of the interference filter C. In addition, there is also the possibility of multiple reflection within the long-afterglow and / or fluorescent layer B. The reflected light rays are therefore not lost, but instead they can be emitted again in the direction of the interference filter C after renewed absorption and subsequent emission or after repeated reflection. Depending on the angle at which they hit the interference filter C, they can then either pass through it unhindered or they are again reflected back in the direction of the long-afterglow and / or fluorescent layer B. This increases the luminance perpendicular to the interference filter C and at the same time reduces the intensity of the light emitted from the side.

Examples example 1

In Example 1, a plate made of polyvinyl chloride coated with long-afterglow and / or fluorescent copper-doped zinc sulfide was provided with a commercially available interference film (Optical Lighting Film from 3M) and measured by lighting technology, ie the luminance in mcd / m ^{2 was} measured after a different length Time determined. The results obtained are shown in FIG. 2 as a solid line and in Table 1, row 1.

Example 2

In Example 2, the long-afterglow and / or fluorescent plate from Example 1 without interference filter was also measured by means of light technology in a manner analogous to Example 1, which is shown in FIG. 2 as a dashed line and in Table 1, row 2.

Example 3

In example 3, a plate of aluminum coated with europium and dysprosium-doped strontium aluminate was provided with an interference filter (Optical Lighting Film from 3M) and was also measured by light technology analogously to Examples 1 and 2. The results obtained are shown in Fig. 3 as a solid line and in Table 1, row 3.

Example 4

For comparison purposes, the long afterglow and / or fluorescent plate of Example 3 without interference filter measured.

Example 5

In Example 5, a plate of polyvinyl chloride coated with long-afterglow and / or fluorescent copper-doped zinc sulfide was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type BEF II 100/31) and measured by light technology, ie the luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 5.

Example 6

In Example 6, a plate of polyvinyl chloride coated with long-afterglow and / or fluorescent copper-doped zinc sulfide was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type BEF II 90/50) and measured by lighting technology, ie the luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 6.

Example 7

In Example 7, a plate made of polyvinyl chloride coated with long-afterglow and / or fluorescent copper-doped zinc sulfide was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type TRAF II) and measured by lighting technology, ie the luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 7.

Example 8

For comparison purposes, the long afterglow and / or fluorescent Measure the plate of Examples 5 to 7 without interference filter using light technology.

Example 9

In Example 9, a plate made of aluminum coated with long-afterglow and / or fluorescent strontium aluminate doped with europium and dysprosium was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type BEF II 100/31) and measured by lighting technology, ie it was measured Luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 9.

Example 10

In Example 10, a plate made of aluminum coated with long-afterglow and / or fluorescent strontium aluminate doped with europium and dysprosium was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type BEF II 90/50) and measured by lighting technology, ie it was measured Luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 10.

Example 11

In Example 11, a plate made of aluminum coated with long-afterglow and / or fluorescent strontium aluminate doped with europium and dysprosium was provided with a commercially available interference film (Brightness Enhancement Film from 3M, type TRAF II) and measured by lighting technology, ie the luminance in mcd / m ^{2 determined} after a different length of time. The results are shown in Table 1, Row 11.

Example 12

For comparison purposes, the long afterglow and / or fluorescent Measure the plate of Examples 9 to 11 without interference filter using light technology.

Example 13

In Example 13, the long afterglow and / or fluorescent plate of the Example 5 measured at an angle of 60 ° using lighting technology.

Example 14

In example 14, the long afterglow and / or fluorescent plate of the Example 6 measured at an angle of 60 ° using lighting technology.  

Example 15

In Example 15, the long afterglow and / or fluorescent plate of the Example 7 measured at an angle of 60 ° using lighting technology.

Example 16

In Example 16 the long afterglow and / or fluorescent plate of the Example 8 measured at an angle of 60 ° using lighting technology.

Example 17

In Example 17, the long afterglow and / or fluorescent plate of the Example 9 measured at an angle of 60 ° using lighting technology.

Example 18

In Example 18, the long afterglow and / or fluorescent plate of the Example 10 measured at an angle of 60 ° using lighting technology.

Example 19

In Example 19, the long afterglow and / or fluorescent plate of the Example 11 measured at an angle of 60 ° using lighting technology.  

Example 20

In Example 20, the long afterglow and / or fluorescent plate of the Example 12 measured at an angle of 60 ° using lighting technology.

It should be noted that the luminance shown in Table 1 and in FIGS . 2 and 3 was determined in accordance with DIN 67510 Part 1.

Table 1

Luminance in mcd / m ²

Claims (9)

1. A light that emits light in a long-lasting manner and / or fluoresces render object that has at least one long afterglow or fluores ornamental phosphor or a mixture of two or more thereof. 2. Object according to claim 1, characterized in that the object is provided with at least one interference filter. 3. Object according to claim 1 or 2, characterized in that the inter reference filter in the form of a film or vapor deposition. 4. Object according to one of the preceding claims, characterized in that the object has at least the following elements:

• a) a carrier layer,
• b) at least one long-afterglow and / or fluorescent layer arranged over the carrier layer,
• c) at least one interference filter arranged over the afterglow and / or fluorescent layer.

5. Object according to claim 5, characterized in that the at least a long-afterglow and / or fluo arranged above the carrier layer residing layer has at least one phosphor.   6. Object according to claim 5 or 6, characterized in that between the carrier layer and the at least one arranged above the carrier layer nten, long afterglow and / or fluorescent layer a diffuse reflective layer is arranged. 7. Object according to one of claims 5 or 6, characterized in that the carrier layer is diffusely reflective. 8. Use of an object according to one of claims 1 to 7 as Si security marking. 9. A method for increasing the luminance of an afterglow and / or fluorescent object, the method comprising at least the following step:

• a) arranging at least one interference filter on the long-afterglow and / or fluorescent object.