NO130989B - - Google Patents

Description

Electrically heated window with multiple glazing.

The present invention relates to an electrically heated multi-pane glass unit comprising a pair of rigid glass plates arranged parallel to each other, an electrically conductive heating device arranged for heating the inner surface of at least one of the glass plates, electrically conductive means for supplying electric current from the outside of the said unit to the said unit heating device and distance bolt means between the said glass plates, and the invention is distinguished by the fact that the distance means is an electrically insulating dehydrator element containing a desiccant, the element being placed between opposite edge parts of the plates, that a pair of power rails is placed between said glass plates in electrical contact with the electrically conductive heating device, the current rails being located within the same edge areas that are occupied by parts of the distance dehydrator element and that the electrically conductive heating device comprises an electrically conductive film which mainly covers the inner surface of the said one p let, and as the conducting bodies feed electric current to said current rails. Furthermore, the busbars according to the present invention can, but not necessarily, be rigidly fixed in relation to the electrically conductive heating circuit. At least according to one embodiment of the invention, the spacer element is a flexible or yielding element which compressibly supports the busbars under slight pressure in physical contact only with the electrically conductive heating device. Consequently, the spacer element for the multi-plate glass unit according to the invention can be used not only to separate the glass plate components in the unit and to dry the air space between them, but also to electrically isolate the electrically conductive heating device from any metallic frame and/or mounting frame that may be provided for the device, besides hiding or

completely covering the busbars, carrying and uniformly applying pressure to the busbars held only in pressure contact with the electrically conductive heating device, eliminating the need to remove electrically conductive film from the edge portions of the film-coated surface of a glass sheet and/or remove sprayed-on film material from the outer surface of a glass substrate, and eliminate the operations required to rigidly attach the busbars in relation to the electrically conductive heating device if this is desired.

The above-mentioned and additional purposes, characteristic features and advantages of the invention will appear more clearly from the following description with reference to the drawing, where there is shown a perspective view, partly in section of a multi-plate glass unit which includes the basic ideas of the invention.

The drawing shows a typical example of an electrically heated multilayer glass unit according to the invention. As shown, the multi-plate glass unit 10 consists of two glass plates 12 and 14 arranged parallel to each other and spaced apart to form an insulating air space between the plates. The glass sheets 12 and 14 may be tempered, colored, laminated, shaded, coated or have other special properties with regard to strength, optical or solar radiation control.

As will further be seen, the glass plate 12 is provided with an electrically conductive heating device which comprises a transparent electrically conductive coating or membrane 16 on its inner or air space surface. The electrically conductive membrane 16 is arranged for heating the adjacent glass plate substrate 12. The principle reason for this type of unit construction is that these units are intended for use in windows for areas occupied by people to provide an insulating window having the inner glass plate heated to avoid the inconvenience caused by drafts and/or a glass panel that is heated to eliminate the formation of condensation on it.

In connection with the present invention, any desired method can be used to produce an electrically conductive heating device, such as the membrane 16. It can e.g. a preferred method is used, where a transparent, electrically conductive copper film with excellent solar control properties is deposited on a glass plate surface, which method is described in detail in a previously submitted application and another method that can be used, where a transparent film of electrically conductive tin oxide is arranged on a glass plate substrate, is shown in detail in U.S. Pat. patent 3,107,177. Other methods which may also be used include sputtering and vacuum deposition of electrically conductive films, as well as methods of providing an electrically conductive circuit consisting of fine wires and the like, as shown in U.S. Pat. patents 2,813,960 and 2,932,710. It is thus within the considerations of the present invention that any electrically conductive heating device or membrane can be used, and any organs or methods can be used to produce the desired heating circuit.

As shown in the drawing, the glass plate 12 and more precisely the electrically conductive membrane 16 is also provided with a pair of busbars 18 and 20 located at opposite edge areas of the glass plate and in electrical contact with the transparent electrically conductive membrane. For reasons that will appear later, the busbars 18 and 20 may, but must not necessarily, be rigidly attached to the glass plate 12 and/or the electrically conductive membrane 16. Other arrangements of the busbars than the one shown, including the use of further busbars on the glass plate 14, interconnected with the busbars on the glass plate 12, can also be used if desired. As will be seen, the busbars 18 and 20 are connected to conductors 36 and 38 in a suitable manner to supply current from an external source (not shown) to the membrane 16 and thereby heat the membrane and its accompanying glass plate substrate.

In accordance with the preferred embodiment of the present invention, the glass plates 12 and 14 are separated at their edge regions by an electrically insulating spacer-wiper element 22. The spacer-wiper element 22 shown in the drawing has a substantially rectangular cross-section and extends completely around the circumference of each of the glass plates 12 and 14 in contact with their inner edge portion surfaces. Along these opposite edge portions of the glass plate 12 which are provided with busbars 18 and 20, the spacer-wiper element 22 preferably rests against the busbars and occupies essentially the same area of the glass plate as that occupied by the busbars.

Although the spacer wear element 22 is not shown bonded to the adjacent edge areas of the glass plates 12 and 14 and/or adjacent surface portions of the busbars 18 and 20, it is within the scope of the invention that it can be bonded in this way, preferably by means of a continuous film or bead of an adhesive, moisture-resistant, non-electrically conductive sealant that would provide a primary hermetic seal for the unit.

In lieu of or in addition to the provision of a primary hermetic seal, there is shown a flexible, moisture-resistant strip 24 with a bead or layer of moisture-resistant, non-conductive sealant 26 bonded thereto and to the circumferential edge of the spacer-wiper element 22 and the circumferential edges 28 of the glass plates. The strip 24 and the sealant 26 extend completely around the perimeter of the unit 10.

Also shown is a rigid frame member 30 of substantially U-shaped cross-section extending around the entire circumference of the unit 10. The frame member 30 typically consists of several sections of metal channels which are joined or butted at their ends. The angle which the flanges or the sides of the channel elements form with the central or stepped portion of the channel elements is somewhat less than 90°. When the channel members are attached to the edges of the glass sheets, these sides are held apart to allow insertion of the glass between them. These sides are then released and spring back into contact with the surfaces of the glass plates. The channel elements are thus kept under tension, or to put it another way, beyond a weak compressive force on the unit's components placed between them. Thus, while the frame member 30 apparently protects the edges of the glass sheets, it also serves to hold the unit together with pressure, particularly when no sealant or adhesive is used to hermetically seal the spacer fabric member 22 to the inner surfaces of the glass sheets 12 and 14 and/or adjacent surface parts of the busbars 18 and 20. Moreover, the compressive holding force beyond the frame element 30 is sufficient to support the busbars 18 and 20 in effective electrical contact with the membrane 16 without the necessity of rigid mounting of the busbars opposite the membrane 1 such as by soldering the busbars to the membrane 16 or attaching metal-ceramic busbars to the glass plate 12.

The spacer drying element 22 in the drawing is composed of a desiccant 32 finely distributed in an electrically insulating, moisture vapour-transmitting, mat material 34. The function of this material 34 is to provide an electrically insulating spacer as well as to produce the necessary communication between the air space in the unit 10 and the drying material 32, so that moisture from the air inside the unit will be absorbed by it mainly evenly. finely divided drying agent. In addition to the above-mentioned properties, the matrix material 32 is preferably also a material that is flexible or easily deformable at room temperature to any shape or profile that can be found, such as by pressure forming to or around adjacent surface portions of the busbars 18 and 20.

A preferred spacer drying element which exhibits all the above-mentioned properties is preferably a thermoplastic, elastomeric element produced in the following manner and with the following composition:

Pellets of the first component (Thermolastic 226) are fed to a two-roller heated to a temperature of approx. 121°C. The pellets are allowed to soak for approximately 5 minutes before the mold is started. The pellets are then ground thoroughly until a smooth plate of the material is formed. Powdered "Linde Molecular Sieve 13X" is slowly added to the plate of "Thermolastic 226" and after adding all the material in the second component, the resulting sheet or plate is taken off and quickly returned to the mold at least five times. This process of adding material, removing and returning it to the mold is then repeated with the addition of kjdnnrdk. Kjdnnrdk is only used as a color additive and the application is not essential. The finished composition is removed from the mold and cut into strips with a width of 12.7 mm which are stored in a sealed container until later extrusion into the desired shape.

A shape is chosen to give the desired contour of the spacer wear element. This mold is placed in an extruder of the "Killion 100" type. The extruder's drum is heated to approx. 121°C

and the mold is heated to approximately 115-126°C. The extruder's screw speed setting is approximately 2.5. The previously prepared 12.7 mm wide strips of the material having the desired composition for the spacer-drying element are then fed into the feed hopper and extruded into the desired shape.

"Thermolastic 226" is a particular example of a particularly suitable member within a group of electrically insulating, moisture vapor permeable, thermoplastic elastomers, as described in U.S. Pat. patent 3,265,765- In connection with the present invention, however, other electrically insulating, thermoplastic, moisture vapor transmitting materials can also be used, as well as electrically insulating, moisture vapor transmitting, thermosetting materials and vulcanizable materials. Examples of materials in addition to "Thermolastic 226" that can be used: Polyacrylate elastomers, acrylonitrile-butadiene copolymers, polybutadiene elastomers, silicone elastomers, polyamide resins, urethane elastomers, epoxy resins, polyester resins, phenolic resins, urea formaldehyde resins, cellulose acetate resins, polycarbonate resins, polystyrene resins, polyvinyl alcohol resins, vinyl chloride-vinyl acetate-sampolin resins, ethylene-vinyl acetate copolymers and the like.

The preferred type or group of drying materials which can be used in connection with the development of the present invention and which are now covered by patents on the composition of materials, are the synthetically produced crystalline metals, aluminum silicates or crystalline zeolites. "Linde Molecular Sieve 13X" in powder form is a particular example of a synthetically prepared crystalline zeolite which is particularly satisfactory and which is covered by U.S. Pat. patents 2,882,243 and 2,882,244- However, other desiccants or absorbent materials can also be used, such as anhydrous calcium sulfate, activated aluminum oxide, silica gel and the like.

In accordance with the above description of a particular embodiment of the invention, it will be clear that the electrically heated multi-plate glass unit shown and described here can produce a number of unique advantages compared to similar known constructions. Among these advantages are: Isolation of the electrically conductive heating element and the busbars from any metallic frame and/or surrounding mounting frame that may be provided for the unit, hidden or completely covered placement of the busbars in a direction perpendicular to the glass plates of the unit by allowed to occupy the same edge area of the glass plate areas that are normally hidden and occupied by the spacer element, elimination of the need to remove electrically conductive film from the edge parts of the glass plate substrate, which could lead electric current to and/or from a spacer element because this spacer element according to the invention is together made of electrically insulating material and therefore will not conduct electrical current, and the elimination of the previously necessary processes for rigidly fixing the busbars in relation to the electrically conductive heating element by the use of a compressible spacer that can evenly and with pressure hold the busbars in active electrical contact with the electr ic conductive heating device by mere pressure. The preferred unit according to the invention also has excellent aesthetic appeal, not only because the power rails are hidden,

but also because the completely smooth upper surface and black color of the spacer element does not attract visual attention to the fact that a spacer element exists between a pair of glass plates.

Claims (4)

•1. Multi-plate glass unit (10) comprising a pair of rigid glass plates (12, 14) arranged parallel to each other, an electrically conductive heating device (16) arranged for heating the inner surface of at least one of the glass plates (12), electrically conductive means (36, 38) for supply of electric current from the outside of the aforementioned unit (10) to the aforementioned heating device (16) and spacers (22) between the aforementioned glass plates, characterized in that the spacers (22) are an electrically insulating dehydrator element that contains a desiccant, the element being placed between opposite edge parts of the plates (12, 14), that a pair of current rails (18, 20) are placed between said glass plates in electrical contact with the electrically conductive heating device (16), the current rails being located within the same edge areas occupied by parts of the spacer dehydrator element (22) and that the electrically conductive heating device (16) comprises an electrically conductive film which mainly covers the inner surface of the said one plate, and as the conducting bodies (36, 38) feed electric current to said current rails (18, 20). 2. Glass unit according to claim 1, characterized in that the desiccant material which is known per se is dispersed in is a base mass of electrically insulating, moisture vapour-transmitting material. 3. Glass unit according to claim 2, characterized in that the electrically insulating material which is known per se consists of a flexible material. 4. Glass unit according to claims 1 and 3, characterized in that when the current rails (18, 20) are not firmly connected to the heating device (16), the said spacer dehydrator element (22) compressibly supports said current rails (18, 20) in electrical contact with the electrically conductive heating device (16).