US20110168429A1

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Publication number: US20110168429A1
Application number: US13/048,414
Authority: US
Inventors: Neil McDonough; Daniel P. Segall; Iris E. Hilton; John R. Pennace
Original assignee: Flexcon Co Inc
Current assignee: Flexcon Co Inc
Priority date: 2002-04-10
Filing date: 2011-03-15
Publication date: 2011-07-14
Also published as: US20070298203A1; AU2003221876A1; US20030222573A1; JP2005522834A; CN1656193A; KR100658030B1; CN100408650C; US7279831B2; EP1497392B1; WO2003087257A1; EP1497392A1; KR20050005439A

Abstract

A water vapor permeable composite is disclosed for use in electroluminescent devices. The composite includes polymeric material having a first surface energy, a phosphorescent material dispersed within said polymeric material; and an electrically conductive material on at least one side of said polymeric material. The conductive material has a second surface energy, said the first and second surface energies are each between about 32 dynes/cm and 46 about dynes/cm. The polymeric material has a moisture vapor transmission rate of at least one gram/100 sq. inches for a 24 hour period at 100° F. for a one mil thick barrier.

Description

PRIORITY INFORMATION

The present application is a continuation of U.S. patent application Ser. No. 11/850,182 filed Sep. 5, 2007, which is a continuation of U.S. patent application Ser. No. 10/410,920 filed Apr. 10, 2003 now issued as U.S. Pat. No. 7,279,831 on Oct. 9, 2007 which claims priority to U.S. Provisional Patent Applications Ser. Nos. 60/371,375 filed Apr. 10, 2002, and 60/404,420 filed Aug. 19, 2002.

BACKGROUND OF THE INVENTION

The invention relates to luminescent materials and relates in particular to electro-luminescent devices that include luminescent materials.

Electroluminescent materials generally include phosphorescent particles that are suspended within or coated by a polymeric material. Electroluminescent devices typically provide an electric field in the area of the phosphorescent particles to cause the particles to glow. Such devices may be used for a wide variety of uses such as advertising, lighted keyboards and other such displays, accent lighting in automobiles, backlighting for liquid crystals displays, nightlights, etc.

Such devices typically include a protective layer that is used to keep water vapor from entering the polymeric material. For example, U.S. Pat. No. 6,207,077 discloses a luminescent thermosetting polyester blend that is water resistant; and U.S. Pat. No. 6,198,216 discloses a polymeric matrix that includes luminescent particles and a fluoride resin binder as well as a protective layer. Because the dielectric properties and chemical properties of such luminescent materials typically rely on the exclusion of water vapor, devices incorporating such luminescent materials typically include a moisture barrier. Such moisture barriers may be relatively expensive for certain devices, and may limit the uses of such devices.

There is a need therefore, for an electroluminescent material whose performance is not dependent on the presence or absence of water vapor from the material.

SUMMARY OF THE INVENTION

A water vapor permeable composite is disclosed for use in electroluminescent devices. The composite includes polymeric material having a first surface energy, a phosphorescent material dispersed within said polymeric material; and an electrically conductive material on at least one side of said polymeric material. The conductive material has a second surface energy, and the first and second surface energies are each between about 32 dynes/cm and about 46 dynes/cm. The polymeric material has a moisture vapor transmission rate of at least one gram/100 sq. inches for a 24 hour period at 100° F. for a one mil thick barrier. Due to the relative matching of surface energies, water vapor does not substantially condense at the interfaces between the conductive material and the polymeric material. Water vapor, therefore, may pass through the composite without adversely affecting the operation of an electroluminescent device that includes a composite of an embodiment of the invention.

BRIEF DESCRIPTION OF THE DRAWING

The following description may be further understood with reference to the accompanying drawings in which:

FIG. 1 shows an illustrative diagrammatic view of an electroluminescent composite in accordance with an embodiment of the invention;

FIG. 2 shows an illustrative diagrammatic view of an electroluminescent composite in accordance with another embodiment of the invention;

FIG. 3 shows an illustrative diagrammatic view of an electroluminescent composite in accordance with a further embodiment of the invention;

FIG. 4 shows an illustrative diagrammatic view of an electroluminescent composite in accordance with a further embodiment of the invention;

FIG. 5 shows an illustrative diagrammatic view of a transferable electroluminescent composite in accordance with a further embodiment of the invention;

FIG. 6 shows an illustrative diagrammatic view of an electroluminescent composite formed from the transferable electro-luminescent composite shown inFIG. 5;

FIG. 7 shows an illustrative diagrammatic view of a transferable conductive composite in accordance with a further embodiment of the invention; and

FIG. 8 shows an illustrative diagrammatic view of an electroluminescent composite formed from the transferable conductive composite shown inFIG. 7.

The drawings are shown for illustrative purposes and are not to scale.

DETAILED DESCRIPTION OF THE INVENTION

The invention provides for the development of electroluminescent materials that may be inert to conditions of water vapor penetration and condensation. This permits the packaging of electroluminescent composites to not be required to be water vapor impermeable.

In accordance with an embodiment of the invention, anelectroluminescent composite10 may includephosphorescent particles12 that are dispersed within apolymeric material14 as shown inFIG. 1. It is preferred that all of the phosphorescent particles be coated by the polymeric material, even near the surface of the composite. The polymeric material permits water vapor to pass through the polymeric material as indicated at A and B. The polymeric and phosphorescent particles are chosen so that the surface energies of each material are each within a range of about 32 to about 46 dynes/cm. Water vapor, therefore, will not condense at the interface between the polymeric material and the phosphorescent particles. Because of this, water vapor will not remain within the composite, and the presence or absence of water vapor therefore, will not substantially affect the performance of the composite when the composite is employed within an electroluminescence device. In various embodiments, thecomposite10 may be provided as a product in itself, or may be provided with a carrier (that may or may not be removable) and/or may be provided with one or more adhesive layers on the outer surface of the composite.

In particular, an electroluminescent device using acomposite10 may also include aprotective coating16 and optionally may include a pair of

conductors

18A and18B that are respectively electrically coupled to alternating

current sources

20A and20B as shown inFIG. 2. In other embodiments, thecomposite10 andcoating16 may be placed onto conductors or buss bars at a point of application or use of the device. Theprotective coating16 and

conductors

18A and18B have a sufficiently high moisture vapor transmission rate that water vapor may pass through these materials as well. In addition, the surface energies of each ofprotective coating16 and

conductors

18A and18B are between about 32 to about 46 dynes/cm. Moreover, it is preferred that the difference between the surface energy of the polymeric material and the protective coating remain relatively small, and the difference between the surface energy of the protective coating and the conductors remain relatively small. Water vapor, therefore, will not condense at the interface between the polymeric material and the protective coating, or at the interface between the polymeric material and the conductors. Because of this, water vapor will not remain within the electroluminescent device, and the presence or absence of water vapor therefore, will not substantially affect the performance of the electroluminescence device.

The polymeric material may comprise a pressure sensitive acrylic adhesive film such polyester (PET), polymethylmethacrylate (PMMA), or a thermoplastic coating, polyamides, amorphous polyester resins, acrylic resins, or any other material that provides sufficient moisture vapor transmission and has an appropriate surface energy. It has been discovered that phosphor to polymer ratios of about 25/75 to about 74/26 may be used in various embodiments. For example, a phosphor to polymer ratio of 55/45 may be used in certain embodiments. Again the properties of the continuous polymer layer should be such that the polymeric material has a low enough specific surface energy that water vapor does not condense at the interface of the phosphors and the polymer, polymer and conductive layer, or polymer and polymer layers, yet the layers may allow water vapor to move freely through the composite. The polymeric material preferably may include untreated polyvinyl chloride, or slip treated polyesters with specific surface energies of less than 46 dynes/cm, with preferred specific surface energies of less than 40 dynes/cm.

For the conductive material, indium tin oxide (InTO) may be used, having a surface energy of about 36 dynes/cm. In other embodiments, lightly metallized conductive layers with a specific surface energy of about 40-42 dynes/cm may be used. It is preferred, however, that the surface energy be between about 32 and about 40.

The following table identifies the surface energies and moisture vapor transmission rates of various materials that may be used in various embodiments of the invention.

TABLE 1

	Specific Surface
Material	Energy	MVTR

Polyester	41-44	2.2
Polyester (amorphous)	36-38	2.6
Polymethylmethacrylate	41	3
(PMMA)
Electroluminescent	35-40	n/a
Phosphors
Polycarbonate
46	11
Polystyrene	38	8.5
Rigid PVC	39	3.0
Silicone	24-28	40
Acrylic pressure sensitive	32-38	15-40
adhesives

Materials having a surface energy below about 32 may have difficultly adhering to other materials in forming an electroluminescent device, although the use of silanes or other adhesion promoters may facilitate overcoming a low surface energy adhesion problem. In fact, the use of such a surface treatment (e.g., with silanes) may cause the specific or critical surface energy of the composite to be reduced. For example a coating of reactive silanes, such as a 3/1-ratio gamma glycidyoxypropyl trimethoxy silane to a propyl amino silane, in a concentration of 0.1-5.0% on weight in a dry (water free) solvent on the surface of a higher specific surface energy material such as Aluminum may reduce the surface energy to a non-condensing level (down to the low to mid 30 s dynes/cm). It should be noted that such specific surface energy reductions, which prevent a condensation to water, may also be of value in preventing electrolytic corrosion of metals as the galvanic effect needs water to function. Further, the inclusion of a high moisture barrier as part of the dielectric matrix may have an adverse effect on the performance of an electrolumineseent device of the invention. Such barriers may lead to an out-gassing effect (e.g., bubbles forming in the adhesive layer for example). Such “bubbles” once formed, change the “K” (dielectric constant) and change the separation between conductive layers, thus having an adverse effect on the total capacitance and thus the performance of the electro-luminescent device.

It is preferred that an electroluminescent device of the invention have no layer with an MVTR of less than 1 gram mil/100 sq. inches/24 hrs. (Lyssy test at 38° C. and 90% relative humidity), and that no two successive polymer layers differ by more than 6 gram mil/100 sq. inches/24 hrs, and more preferably not differing by more than 3-gram mil/100 sq. inches/24 hrs. Further, the polymeric material should not have its dielectric value substantially changed by the presence of water vapor, particularly if the polymeric material has a relatively low surface energy level. For example a rubber-based adhesive may show a reduction in dielectric constant of about 50% after 3 days at 100° F. and 95% relative humidity. The increase in dielectric constant may result in a dielectric breakdown within the structure effectively shorting out of the device.

Devices of the invention may be coated or printed as desired in various applications in which the device will be coupled to a power supply. Again, there is no need to exclude water from the device, and in fact, it is preferred that water vapor be permitted to freely pass through each of the layers of the device. The devices may be tested for water sensitivity by placing the devices in a high humidity environment (100° F. and about 100% relative humidity). The devices should then be periodically analyzed for illumination stability.

As shown inFIG. 3, an electroluminescent device in accordance with another embodiment of the invention includes a pair of

conductive layers

22 and24 on either side of the composite10, as well as aprotective layer26. Theconductive layer24 is preferably a transparent conductive layer such as InTO or a lightly metallized aluminum on the order of an optical density of between about 0.07-about 1.0 and preferably between about 0.15 and about 0.30. In other embodiments, the transparent conductor layer may include conductive polymers or carbon nanotubes. The transparent conductive layer should include a sufficient concentration of conductive material such that the conductive layers' product of their resistance and capacitance (RC time constant) defines the frequency of the resistance capacitance layer, and this frequency should be higher than the frequency needed to illuminate the device. As the resistance of the electrically conductive material decreases, the capacitive impedance also decreases as does the total current that is needed to light the phosphors.

conductive layers

22 and24 have a sufficiently high moisture vapor transmission rate that water vapor may pass through these materials. In addition, the surface energies of each ofprotective coating26 and

conductive layers

22 and24 are between about 32 to about 46 dynes/cm. Moreover, it is preferred that the difference between the surface energies of each pair of adjoining layer remain relatively small, preferably less than 6 dynes/cm. Water vapor, therefore, should not condense at any of the interfaces within the device, so water vapor will not remain within the electroluminescent device.

In further embodiments, the device may also include one or two additionaldielectric layers28 and30 (e.g., between about 0.02-about 0.5 mil) between the composite and either or both of the conductive layers to ensure that the phosphorescent particles do not contact directly a conductive layer as shown inFIG. 4. Theprotective film26 may further serve to protect persons from directly contacting any conductor or underlying buss bar or other alternating current source, and may also provide additional structural integrity to the device. Further, a clear protective film may be used to keep dust and scratches out and to lend further structural support for the electroluminescent device. Such films may include polyester, polyolefins, PVC, PVF, polycarbonate, etc. as long as the conditions for adhesion, surface energy and moisture vapor transmission rate are met.

In accordance with yet another embodiment of the invention, a transfer component may be constructed such that thermal transfer printers, or a hot stamping machine may be used to place an electroluminescent composite on a graphic display (e.g., keys on a key board, instrument panel display, etc.). In particular, a transfer component may include a composite10, a transparentconductive layer32, aprotective layer34, arelease layer36 and acarrier layer38, as well as anadhesive layer40 on the opposite side of the composite10 as shown inFIG. 5. The transfer component may be applied to one or

more conductors

42 and44 on agraphic display46 followed by removal of the carrier and release layers36 and38 as shown inFIG. 6. In this process, thecarrier layer36 may serve to provide structural support to an otherwise frangible component that becomes transferred to thedisplay46. In certain embodiments, the polymeric material incomposite10 may include adhesive properties that aseparate adhesive40 is not required. Similarly, in certain embodiments, theconductive layer32 may include sufficient protective properties that a separateprotective coating34 is not required. Further, the conductive layer may include a coating of a dielectric to ensure that no phosphorescent particles contact the conductive layer. The release layer or break coat layer may remain with the composite following transfer in certain embodiments and may itself serve as a protective layer in the final device. The “break coat” can, and sometimes does, also act as the “Protective Coating”.

In still further embodiments, the transfer component may include aconductive layer50 and aprotective layer52 in addition to therelease layer54, thecarrier layer56, and the adhesive layer,58, but not aluminescent composite10. In this case, the receivingsubstrate60 including one or more conductors62 (such as a display) would already include aluminescent composite10. This process of transferring a conductive layer to a luminescent composite may permit discrete transfer of various desired indicia or other graphics that need not be coupled to directly to an alternating current power supply since their role is to bridge an existing gap in the receiving substrate. In certain embodiments, the composite10 may provide sufficient adhesive, for example by including (of about 1% to about 45% and preferably about 2%-about 6%) of an antistatic agent such as CYASTAT sold by Cytec Industries, Inc. of West Paterson, N.J.

Salt may also be employed as an alternating current receptor material in further embodiments of the invention. For example, employing such a material in the bonding adhesive that affixing the luminescent composite to a conductive substrate, may increase the field strength of the electroluminescent device. Alternating current voltages in the range of about 100 volts-about 2500 volts (and preferably between about 400 volts and about 800 volts) at a frequency of about 60 Hz to about 14000 Hz (and preferably between about 1000 Hz and about 5000 Hz) has been found to be effective in devices of the invention. The electrical potential and frequency may be varied for different applications based on, for example, the color desired, the size of the electroluminescent device, the total thickness of the electroluminescent material, the brightness, and the internal impendence and capacitance.

Generally, the higher the frequency, the lower the molecular weight of the salt needed to optimize the results. It has been discovered that salts such as these, which can be reasonably uniformly dispersed within a polymeric matrix, may facilitate the transfer an alternating current signal, which may complete the electroluminescent device circuit. The addition of these charge carrying components may be used either by themselves or in combination with other conductive materials such as the previously discussed vacuum deposited light metal (having an optical density of about 0.15-about 0.40), Indium/Tin Oxide (having resistance between about 25 ohms to about 400 ohms) or other such conductive layer that will allow for the passage of the light generated by the EL device. As an alternative to the conductive salts such as CYSTAT discussed above, other salt like conductive polymers may also be employed. While one charged portion of the conductive polymer (e.g., the cationic portion) is of fairly large molecular weight, the other charge center is typically of low molecular weight.

Further techniques for creating graphic electroluminescent displays may involve masking out with a stencil the graphic items, or even cutting out the graphics from an electroluminescent composite. The desired graphics may then be affixed to a conductor. Since such devices are relatively insensitive to water vapor, they may be used in environments that were previously considered too hostile to electroluminescent devices, such as billboards, sides of busses, airport runways, and floors of retail stores.

Further, such devices may be employed on original documents for security purposes. Such devices may be transferred onto the original document. The device may be designed to provide luminescence only when placed under an alternating current source of a specific frequency.

Those skilled in the art will appreciate that numerous modifications and variations may be made to the above disclosed embodiments without departing from the spirit and scope of the invention.