FI58572C - ELEKTROLUMINISCERANDE GLAS SKIVOR AV ELEKTROLUMINISCERANDE GLAS SAMT METODER FOER FRAMSTAELLNING AV DYLIKA SKIVOR - Google Patents

Description

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Patent and References Board AmSIcm detained and issued Pubticond 31.10.80 (32) (33) (31) Myyduy ocuollcoui — MofSrd prtorhtt (71) (72) Sol Japka, PO Box 235> 33101 Tampere 10, SUomi-Finland (FI) (7) ^) Yrjänä Vuori (5 * 0 Electroluminescent Glass, Electroluminescent Glass Discs and Methods for Making Such Discs - Sähkö-luminisoiva lasi, ähköluminisoivia lasilevyjä sekä menetelmiä sellaisten levy valmistamiseksi

This invention relates to electroluminescent glass sheets or glass rods or the like and their production methods. The present invention particularly relates to methods of enclosing noble gas in glass material.

The method of using electroluminescent glass elements comprising a glass body and noble gas as a luminescent agent, which achieves an ionized illumination, is known before.

The glass body may be a glass plate with porous lattice structure with a porosity of the same atomic size as that of the noble gas. The cell spaces in the lattice structure of the glass can be filled with said noble gas and sealed from the outside to prevent the gas from flowing out of the interstices.

The glass sheet may be of borosilicate glass or of pyrex glass and contain component elements of such an atomic size as to strengthen the effect of the lattice structure of the glass sheet. In order for the glass sheet to receive noble gas atoms of the same size, the component teacher must belong to the same horizontal group in the periodic table as the noble gas. be beside it; oxygen or aluminum atoms for argon gas, calcium or potassium atoms for krypton gas and cadmium atoms for xenon gas, etc.

2 58572

The edge surfaces of the glass sheet may be closed by non-porous glass, the opposite flat surfaces shall be provided with an electrically conductive layer forming plate in an electric capacitor or be coated with a transparent metal film which closes the plate's vectors or should be sprayed with a transparent , electrically conductive metal oxide coating, which closes the disc's surface pores, etc. The metal oxide coating may also be of a type which is soluble in the glass sheet to a certain depth, such as titanium oxide.

Furthermore, it is possible that the glass plate is sketched between ordinary capacitor plates.

In the manufacture of an electroluminescent glass element, one can proceed in various ways.

Can close the edge surfaces of the glass sheet, expose the flat surfaces of the sheet to a noble gas atmosphere maintained under a pressure which allows the noble gas to enter the porosity of the glass, and apply a transparent metal coating to the flat surfaces of the glass sheet to seal the surfaces gas-tight.

Further, during manufacture, it is possible that the glass sheet is subjected to a chemical leaching to increase its porosity, subjected to a noble gas atmosphere maintained at a temperature and pressure which allows the noble gas to enter the porosity of the leached glass, and the hot glass sheet is cooled to close the pores of the disc to enclose the gas.

The present invention intends to extend the use of the method described above. The invention is most characterized. by first producing the glass sheet or element with porous lattice structure, heist of borosilicate or pyrex glass and covering the entire surface with non-porous material.

Then, through two heels in the non-porous surface, the enclosed glass pores are filled with noble gas and the heels are closed by a suitable method, but heist with two metal rods or metal pipes. These can also act as electrodes to activate and ionize the entrapped gas to emit light with alternating current or VHF or UHF electromagnetic radiation with path lengths of a scale from one centimeter to one millimeter, while the thickness of the glass sheet rises to about half a path length.

Noble gas can be enclosed in the covered glass sheet with metal pipes by the following two methods. With respect to the glass plate with two metal tube electrodes, a tube, open at the upper end, can be measured into the interior of the tube glass. noble gas, e.g. helium or argon or neon under imprinted pressure from a container containing such gauge, or by means of a vacuum pump connected to the second moving electrode, until the porous structure of the glass sheet is belt filled. Then both metal pipes are sealed with metal or non-porous glass. It is also important to drill a small heat through the center of the non-porous glass tube and leave the drill as the central conductor for the coaxial cable.

The metal rod or tube used should have the same coefficient of expansion or slightly greater than that of the non-porous glass to suitably heated, heist by induction heating, to form a gas-tight seal. The metal tube need not be sealed to its entire length, the closure of the upper, open end of the tube, which is in contact with the inner porosity of the glass, is sufficient.

Another similar method of enclosing noble gas in the porous interior of a glass plate with two metal tube electrodes is based on low temperature physics.

Helium (liquid helium IV) remains liquid at about four degrees Kelvin (4 ° K) above the absolute zero point, and when further cooled below two degrees Kelvin (2 ° K) it transforms into another liquid gas called liquid helium II.

Liquid helium II has remarkable physical properties when floating on glass surfaces or in containers. If a small sample glass is dipped in a container of liquid helium II, this liquid helium II floats up along the outside of the sample glass, over the edge and fills the sample glass to the same level as the helium in the container. This physical phenomenon can be used to fill glass sheets with metal tubes protruding from the interior of the panel. They are immersed in a bath of liquid helium II til the edge of the panel.

Liquid helium II then flows up along the outer surface of the metal tube, over the edge and then into the interior of the tube to fill the porous interior of the glass sheet. This phenomenon applies to metal pipes as well as glass surfaces.

The composite glass sheets may, for practical purposes, be geometrically equal to the smooth flat rectangular test glass containing borosilicates and sufficiently narrow channels in the uncrystallized network of borosilicate and pyrex glass structure, reducing the viscosity of superfluid n temperature of about one to two degrees Kelvin (1 ° K - 2 ° K).

The sunken glass plate is slowly lifted out of the bath by liquid helium II and slowly warmed to normal temperature. At higher temperatures than four degrees Kelvin, liquid helium becomes a gas that expands to fully fill the internal norocity of the composite glass sheet by gas pressure. The extra amount of helium gas that develops penetrates through the metal tubes to be closed by expansion of metal or glass plugs, heist through inductive heating ·

Another method of using liquid helium II superfluidity is that the metal rods or tubes of the composite glass sheets have an outer diameter which differs from the inner diameter of the drilled -4 'g heels in the glass plate by 5 x 10 cm - 5 x 10 cm. This allows the super-fluid flow of liquid helium to penetrate the inner porosity of the glass sheet. The tubes are then closed by tube expansion, heist by induction heating. One method of making a difference of about 5 x 10 cm is to drill heels through the composite glass plate, and leave the drills standing to form two metal electrodes with a bore created during the drilling between the drill diameter and the heel of the glass sheet.

It is desirable to use as a non-porous glass a suitable technical glass of sufficient strength to withstand a large internal pressure and also with sufficient expansion and heat conduction coefficients. This type of technical glass is necessary to enclose the horosilicate sheet.

In order to transmit microwave energy through the entire length of the glass sheet or glass rod, or through similar glass elements, the outer glass surface is covered with electrically conductive glass, so that the entire glass structure acts as a hollow space resonator with microwave energy fed through the two hollow metal tube electrodes. microwave that develops path lengths from one millimeter to one centimeter. Metal electrodes must be isolated from the outer electrically conductive glass with a non-conductive glass ring of the same depth as the thickness of the conductive glass surface.

If the electrically conductive glass is not intended to conduct electricity, but only to repel internal microwaves, it is preferable that the conductive glass be covered with a layer of ordinary non-conductive glass. Another possible construction can be carried out such that the borosilicate glass is covered with non-frozen electrically conductive vanadium glass and the conductive glass is then covered with ordinary non-conductive glass. The borosilicate glass insulates the metal electrodes from the interior of the vanadium glass sheet, but requires a similar non-conductive glass ring to seal the heel drilled through the vanadium glass.

The kettle rods or tubes can serve as designers, dipped in molten glass to form uncoated glass sheets, first of porous borosilicate glass and then dipped in non-porous molten glass, covering the entire surface, if necessary, with electrically conductive glass. the glass plate acts as a guide.

For a cavity resonator or closed guide, the entire surface should have a coating of conductive glass and for open guides both glazing edges, as parallel to the tube electrodes, should be uncovered by such glass. This is possible by methods known in glass technology.

An embodiment of the electroluminescent glass sheet and its use according to the invention is illustrated by the accompanying drawings, in which fig. 1 is an axonometric view of a glass sheet ABCDEFHK according to the invention and fig. 2 is a picture of the same glass sheet geometry , E ,, F "H ,, Ku in a conventional technical production of guide, but of a construction according to inventions of normal and electrically conductive glass so that it functions simultaneously as a guide as well as a cavity resonator. Not hara as a guide or a cavity resonator. In conventional manner, in Fig. 1, the electroluminescent glass sheet consists of a square or rectangular glass plate (G ·) of borosilicate or pyrex glass. The entire surface is covered or covered with non-porous glass (G1) and when used. as a guide or as a cavity resonator (closed guide), it has an additional surface coating of electrically conductive glass (G ”).

Both coaxial cables (M and M ') may be enclosed in metal tubes which serve to fill the glass plate with noble gas from a pressurized container. The noble gas enters one of these pure metal pipes and to the other is connected a vacuum pump, heist a mercury-meadow pump or the like.

Where the inner porosity of the glass sheet is to be filled with liquid helium by means of low-temperature technology, the annular gap between the inner diameter of the metal tube (M) and the diameter of the heel (0) -4 -5 should have a difference of 5 x 10 - 5 x 10 cm.

The metal tube (M) acts as a hollow electrode and the metal rod (P) as a probe for the transmission of microwave energy into the glass slab-cavity resonator, where the glass slab is used as a guide (V V ') or a cavity resonator (L L'), M) and the probe (P) are connected to a coaxial cable coming from the microwave generator or the magnetron or klystron or a similar microwave generator.

Both metal tubes (M and Mr) can also serve as conventional electrodes enclosed in the glass sheet to conduct high frequency AC current between the beds to activate the entrapped noble gas atoms so that they become ionized and emit light in the same way as a gas.

Claims (11)

A method of enclosing a flue gas in a glass material having a porosity of the same atomic size as a noble gas, and a method of providing an electrically illuminated element for ionized illumination by applying a strong alternating current or a high-frequency field to the flue gas using an electrically conductive, non-conductive stable film, metal oxide coating, capacitor plates or similar elements, characterized in that after the production of glass with a porous lattice structure the whole surface is coated with a non-porous material except for the hole through which the glass pores inside the element are filled , can be conducted electricity. A method of enclosing a noble gas in a glass material according to claim 1, characterized in that two metal rods or hollow metal tubes are formed inside the glass sheet, forming said holes, preferably parallel to each other near opposite edges of the length of the glass sheet. A method of enclosing a noble gas in a glass material according to claim 1, characterized in that when the glass body has the geometric shape of a cylindrical rod in which two coaxial metal rods or hollow metal flag tubes are enclosed in the same central axis of the cylindrical glass rod at opposite ends or a single metal rod or a single hollow metal tube extending coaxially over the entire length of the cylindrical glass rod. A method of enclosing a noble gas in a glass material according to claim 2 or 3, characterized in that two hollow metal tubes enclosed in the element extending through the non-porous glass coating of said glass element are used to fill the glass material with flue gas by passing noble gas to the the metal tube being connected to the vacuum pump to provide a greater gas pressure gradient to allow the noble gas to penetrate the porous interior of said glass sheet or cylindrical glass rod. 10 58572 A method of enclosing a noble gas in a glass material according to claim 2 or 3, characterized in that the outer diameter of the two metal rods or hollow metal tubes enclosed in the element is approximately 5 x 10 cm smaller than the inner diameter of the hole in the glass sheet. internal porosity at a temperature of one to two degrees Kelvin when said glass element is completely immersed in a supernatant helium II bath or when protruding metal rods or hollow metal tubes are immersed in a running helium II bath and the supernatant helium rises into the outer surface of the metal rod or tube. into the opening to penetrate the internal volatility of the glass sheet. A method of enclosing a noble gas in a glass material according to claim 1, characterized in that to provide said holes, metal rods or tubes according to claim 1 or 3 are mounted on the glass material before the entire surface of said glass sheet or cylindrical glass rod is sealed with non-porous glass. A method for enclosing a noble gas in a glass material according to claim 1, characterized in that two holes required for filling the noble gas are drilled in the non-porous surface material. A method of enclosing a noble gas in a glass material according to claim 5, characterized in that the drills in the holes are left to act as metal electrodes in said glass element, wherein the clearance between the groove diameter and the drilled hole diameter -5 is about 5 x 10 cm. A method of enclosing a noble gas in a glass material according to claim 1 or 3, characterized in that metal rods or hollow metal tubes are used to enclose the gas (after filling said glass element) by thermal expansion of said metal rods or tubes by induction heating. A method of enclosing a noble gas in a glass material according to claim 2 or 3, characterized in that these metal rods or hollow tubes act as electrodes either to expose the glass body to alternating current or to an electromagnetic field of VHP or UHF or to conduct the glass body.