Abstract: A furnace is provided for the heating of glass sheets to be bent, whereby precise control of the temperature profile across a sheet may be achieved, resulting in improved control over the shape to which the sheet is bent. The furnace has at least one differential heating zone provided with a plurality of main heating elements, and at least one shield for directing heat radiated by said heating elements whereby a controlled differential heating of the glass sheet may be achieved. Transport means, e.g. wheeled boxes, are provided to advance the sheet through the furnace and bending means, e.g. gravity bending ring moulds, may bend the sheet either during, or subsequent to, the heating step.

Abstract: A method for heating and forming a glass sheet includes the steps of heating a glass sheet to at least a first predetermined temperature, applying microwave energy to the glass sheet to heat the glass sheet to at least a second predetermined temperature, cooling an outer surface of the glass sheet to at least a third predetermined temperature and forming the glass sheet using forming rollers to a predetermined configuration.

Abstract: In a method and apparatus for bending glass plates, the glass plates are heated in a horizontal position in a continuous furnace (1) to the bending temperature and in a following bending chamber (5) are pressed by an upwardly flowing hot gas stream against a convex bending mold (7) positioned above the conveying plane. The bent glass plates (3') are placed on a displaceable shaping ring (13) and transferred with the latter into a following cooling station (16). The glass plates (3) are raised from the conveying roller train (2) of the continuous furnace (1) by a suction plate (3) are positioned relative to the transfer ring (28) on the latter. With the aid of the transfer ring (28) the glass plates (3) are transferred into the bending chamber, where in the end position of the transfer ring (28) they assume the desired end position relative to the bending mold (7).

Abstract: The invention is a method for improving the flatness of nonmetallic substrates and preferably glass disks. The method comprises the steps of mounting the glass disk on a support. The support preferably comprises a refractory metal having a cooling rate substantially similar to the disk. The disk is then subjected to heating to a temperature in the anneal region for the given material for a period ranging from about 0.5 hours to 12 hours or longer, and then the disk is controllably cooled. The glass disk is preferably cooled at a rate of about 0.25.degree. C./minute to 1.5.degree. C./minute to room temperature. The invention also comprises a hard disk glass memory element and a data storage and retrieval device comprising this element.

Abstract: An insulation panel is formed comprising a binderless, heat bonded glass fiber insulation board encapsulated within a partially evacuated, gas-tight envelope. The insulation board is formed by laying down discrete length glass fibers into a thin glass fiber mat with the glass fibers lying predominately in and randomly oriented in planes extending substantially parallel to the major surfaces of the thin glass fiber mat. The thin glass fiber mat is layered to form an uncompressed thick glass fiber blanket. The thick glass fiber blanket is heated to a temperature between about 25.degree. C. below and about 20.degree. C. above the strain temperature of the glass fibers; compressed to its final thickness and density; and cooled to form the binderless, heat bonded glass fiber insulation board having glass fibers lying predominately in planes which extend parallel to the major surfaces of the insulation board. The insulation board is encapsulated within the gas-tight envelope to form the insulation panel.

Abstract: There is disclosed a method for molding an optical element, by preparing an upper mold member and a lower mold member for press molding a glass material, heating the mold members together or individually to a predetermined temperature, deforming the glass material according to molding faces of the mold members by a pressing force applied to the mold members, then transferring the mold members and the molded glass to a cooling step and subsequently taking out the molded glass by opening the mold members, thereby transferring the optically functional faces corresponding to the molding faces of the mold members, to the glass material.

Abstract: The invention relates to a method and apparatus for developing an edge stress in a windshield bending furnace. Adjacent to a ring mould is located a metallic, flat extra frame in a manner that the lower surface of a bent windshield remains at a small distance from extra frame. The compression stress of glass edge can be adjusted by varying the distance of extra frame from glass and/or by varying its glass-oriented dimension.

Abstract: The method of making a glass diffusion cell which utilizes taking of an inner glass tube and forming an enlarged annular flange at one end of this tube and in the sidewall of this tube forming a refilling port and a sampling port. This inner glass tube is then located within an outer glass tube with the end of this outer glass tube that is located directly adjacent the enlarged annular flange being sealed to the inner glass tube. The sidewall of the outer glass tube is then spot heated which permits a refilling tube to be connected to the refilling port and a sampling tube to be connected to the sampling port establishing a fluid interconnection with the interior of the inner glass tube. Inlet and outlet tubes are connected to the sidewall of the outer glass tube which fluidly connect with the annular chamber located between the inner glass tube and the outer glass tube. The bottom wall of both the inner glass tube and the outer glass tube are then sealed.

Abstract: The glass sheet is heated to a heat-softened condition in a furnace, and conveyed to a prescribed position above an upper shaping surface of a ring mold. The sheet is then transferred onto the ring mold by lowering part of the conveyor means, and bent by a process involving raising both the ring mold and the conveyor means. This combination minimizes the introduction of optical distortion into the sheet. A preferred bending process is to press bend the sheet between the ring mold and an opposed upper bending mold.

Abstract: Glass sheets which have been heated to bending temperature are bent by passing the glass sheets over a shaping bed having a substantially circular or substantially conical profile of revolution as seen in the longitudinal direction of the shaping bed. The shaping bed is composed of an assembly of revolving elements adapted for driving the glass sheets and at least one hot air cushion acting on the glass sheets in the first part of the bending zone.

Abstract: A glass sheet bending method is performed by apparatus (20) including at least one deformable mold (22) has a linkage (26) that extends between mold members (24) and includes connector links (28) fixed to the mold members and having pivotal connections (32) to each other about axes that extend parallel to the glass sheet throughout the bending, and the linkage also has control links (34) that have pivotal connections (36) about axes that extend perpendicular to the glass sheet throughout the bending as well as having universal connections (38) to each other such that the linkage moves the mold members for bending with a constant radius of curvature. The bending apparatus (20) preferably has a pair of the deformable molds (22,44) that are arranged in lower and upper locations and have respective linkages (26,48) as well as having the mold members (24,46) thereof provided with quench openings (66) through which quenching gas is supplied to quench the bent glass sheet for heat strengthening or tempering.

Abstract: The invention relates to a method and furnace apparatus for bending and tempering glass sheets. A glass sheet is supported on the same outline mold throughout the entire handling process. A bending furnace (10) is designed to be sufficiently long in the traveling direction for carrying a partially bent glass sheet towards a tempering section (16) in such a manner that the glass sheet reaches its final shape during the passage occurring within the bending furnace (10). For this purpose, the glass sheet is heated in the bending furnace (10) with such a high effect that it reaches its tempering temperature before reaching its final shape. The movements and heating of glass sheets are controlled individually on the basis of the thickness and measured temperature of each glass sheet.

Abstract: Glass sheet bending apparatus (20) including at least one deformable mold (22) has a linkage (26) that extends between mold members (24) and includes connector links (28) fixed to the mold members and having pivotal connections (32) to each other about axes that extend parallel to the glass sheet throughout the bending, and the linkage also has control links (34) that have pivotal connections (36) about axes that extend perpendicular to the glass sheet throughout the bending as well as having universal connections (38) to each other such that the linkage moves the mold members for bending with a constant radius of curvature. The bending apparatus (20) preferably has a pair of the deformable molds (22,44) that are arranged in lower and upper locations and have respective linkages (26,48) as well as having the mold members (24,46) thereof provided with quench openings (66) through which quenching gas is supplied to quench the bent glass sheet for heat strengthening or tempering.

Abstract: A method for the preparation of glass sheets with a view to laminating them consists of curving the glass sheets by causing them to pass one after another along a curved trajectory, then cooling them by passage between blowing chests, and of dispatching them by batches to the assembling station, and a laminated pane, the sheets of which have, in the central zone, a core compressive stress of from 1 to 50 MPa.

Abstract: A method and a furnace for bending glass sheets. Glass sheets are heated to a bending temperature by supporting them on a mould (11) and carrying them from one heating station to another. In a bending station (4), the glass sheet is heated for effecting a desired bending partially or entirely through the action of gravity. During a bending operation, the temperature distribution of a glass sheet is subjected to the action of convection blasting. By focusing the blast on the mid-section of a glass sheet it is possible to create a progressively curving pocket.

Abstract: The present invention provides a glass sheet shaping arrangement whereby a glass sheet may be conveyed through a shaping station without being shaped and deposited into a glass collector beneath an upstream portion of the adjacent quench without impacting the lower quench or interfering with the operation of the quench. A furnace, shaping station and cooling station are all linearly aligned so that a glass sheet progresses through the glass sheet shaping arrangement without changing its advancing direction. A glass sheet is conveyed in a first direction along a first generally horizontal plane through the furnace to heat the sheet to its heat softening temperature. The sheet continues into the shaping station where it is lifted into engagement with an upper vacuum surface.

Abstract: The invention relates to a bending and tempering station for glass sheets, comprising an archable roll conveyor and upper and lower tempering boxes (5, 7) provided with tempering orifices (8, 6). The upper tempering boxes (7) are fitted with a number of press rollers (11) having a top rest position and a bottom working position. The rollers (11) are capable of moving against the force of a pneumatic spring (17) from the working position towards the rest position. The pneumatic spring (17) can be further used for operating the rollers (11) between the working position and the rest position.

Abstract: A method for the preparation of glass sheets with a view to laminating them consists of curving the glass sheets by causing them to pass one after another along a curved trajectory, then cooling them by passage between blowing chests, and of dispatching them by batches to the assembling station, and a laminated pane, the sheets of which have, in the central zone, a core compressive stress of from 1 to 50 MPa.

Abstract: A novel display panel (10) has a high fidelity visual pattern with a full range of grey scale values, for instance, a marble or leather pattern, which is produced via a novel methodology (20). In accordance with the novel methodology (20), a high resolution visual pattern (31) and a mask pattern (32) are produced and separately printed. The patterns (31, 32) are then superimposed and exposed to a camera (33) which generates an enlarged photograph positive. A silk screen is produced from the enlarged photograph positive and used to print a high fidelity visual pattern onto a glass substrate (13). The glass substrate (13) and visual pattern (14) are then heated in a tempering oven to derive the display panel (10).

Abstract: A production installation for the contact toughening of glass sheets comprises a horizontal furnace for heating the glass sheets, a press containing two liquid-cooled pressing plates, a feed apparatus for transferring the heated glass sheets into the press and a removal apparatus for removing the toughened glass sheets out of the press. To the lower pressing plate, a solids-transmitted sound pick-up is coupled which, if a glass sheet breaks in the press, supplies an electrical signal. From this signal, after suitable processing of the signal, the control device is triggered, and as a result thereof interrupts the process sequence.

Abstract: Apparatus operable in accordance with the method of the present invention is provided for selectively cooling areas of a glass sheet during heating in the lehr in order to eliminate hot spots and minimize undesirable sagging of portions of the glass sheet. The apparatus includes a gas hearth block upon which the glass sheet is supported during heating and an air nozzle or air nozzles connected to a source of compressed room temperature air located over those areas of the glass sheet that tend to develop hot spots. The air nozzle or air nozzles blow cooler air onto those selected areas of the glass sheet and even out the temperature of the heated glass sheet. This may be done prior to forming and/or tempering the glass sheet. The method and apparatus of the present invention is particularly useful with automobile glazings, such as sidelights and rear windows, bearing peripheral dark banding which show an increased tendency to sag during heating, particularly at the top edge portions.

Abstract: This invention relates to a method and apparatus for forming a glass container by a press-and-blow system wherein the glass container is provided with a reinforced inner surface. According to the inventive method, fuel gas or a gaseous boron or silicon compound is burnt or otherwise reacted inside a parison after the parison molded in the blank mold is transferred to the finish mold. The burning or other reaction of the fuel gas or gaseous boron or silicon compounds can be carried out just prior to the final blow-molding step in which the parison is blow molded into its final shape, simultaneous with the final blow-molding step, or just after the final blow-molding step. The apparatus of the present invention includes a finish mold provided with a blow head which includes a low selector valve. The low selector valve is open during combustion or other reaction within the parison and is automatically closed during the final blow-molding step by the pressure of the compressed air used in the final blow-molding.

Abstract: In a method for bending glass plates, the glass plates are heated in a horizontal position in a continuous furnace (1) to the bending temperature and in a following bending chamber (5) are pressed by an upwardly flowing hot gas stream against a convex bending mold (7) positioned above the conveying plane. The bent glass plates (3') are placed on a displaceable shaping ring (13) and transferred with the latter into a following cooling station (16). The glass plates (3) are raised from the conveying roller train (2) of the continuous furnace (1) by a suction plate (3) are positioned relative to the transfer ring (28) on the latter. With the aid of the transfer ring (28) the glass plates (3) are transferred into the bending chamber, where in the end position of the transfer ring (28) they assume the desired end position relative to the bending mold (7).

Abstract: The invention relates to a method and apparatus for bending and tempering a glass sheet. From a preheating furnace a glass sheet is advanced into a positioning and bending station supported by a gas bed between the stations. In the positioning and bending station the glass sheet is lifted by a ring mold from a gas bed and the glass sheet is heated for gravitational bending to close to a final profile. The glass sheet is pressed to its final profile or shape by an overhead press plate, which also serves as a vacuum pickup for carrying the bent glass sheet into a station for heating for tempering. After tempering, the glass sheet is advanced into a quenching station.

Abstract: A glass vessel edge chamfering method and apparatus wherein heat energy can be controlled readily and chamfering of a glass vessel having a deformed profile, local chamfering and simultaneous processing of the opposite inner and outer sides of a lip of a vessel can be performed readily and besides the efficiency in consumption of energy necessary for chamfering for one glass vessel is improved so that a glass vessel can be processed efficiently in a short time. A pair of positive and negative electrodes are opposed in a predetermined spaced relationship to an edge of a glass vessel, and flame is blown from a pair of burners into gaps between the edge of the glass vessel and the electrodes while a high voltage is applied between the electrodes. Thereupon, electric current flows between the electrodes and the glass vessel by way of the flame and heats the glass vessel by Joule heat when the electric current flows through the glass vessel.

Abstract: A quartz tank member produced by a new method of production having continuous inner corner surfaces formed through bending and welding processes with welded seams being smooth without any hills, valleys, pits, crevasses, or irregularities therein.

Abstract: A traveling vacuum pickup engages heat softened glass sheets in a transfer station and transfers them to one of two shaping stations positioned along opposing sides of a transfer station. After depositing the sheet within one of the shaping stations, the pickup return to the transfer station to receive the next heat softened sheet. The shaping stations may include pressing arrangements that shape successive sheets to different configurations. The vacuum pickup may include two sheet engaging surfaces positioned relative to each other such that as one engaging surface engages a glass sheet and transfers it to one of the shaping stations, the other engaging surface is being positioned within the transfer station to receive the next glass sheet.

Abstract: A heated sheet of glass discharged from a heating furnace is lifted by a ring mold until it is held against a fully continuous lower molding surface of a bent shape of an upper mold. After the sheet of glass is held against the lower molding surface by the ring mold, a vacuum is developed in the upper mold to attract the sheet of glass to the lower molding surface through suction holes defined in the lower molding surface. Thereafter, the ring mold is lowered away from the upper mold to allow the sheet of glass to be bent by the lower molding surface while the sheet of glass is being attracted thereto only under the vacuum developed in the upper mold. The sheet of glass is continuously attracted under the vacuum to the lower molding surface until the sheet of glass is annealed.

Abstract: The invention relates to a method and apparatus for bending and tempering a glass sheet. A glass sheet is supported by one and the same ring mould (3) throughout all its working operations. Following the preheating of a glass sheet from a temperature of about 500.degree. C., its heating to a final bending and tempering temperature is effected at a high output and rate of speed. For example, on 4 mm thick glass, this final heating is performed within a period of time of 15-25 s. Therefore, the temperature of bending station is 800.degree.-1000.degree. C. Since rapidly heating glass bends quickly, the bending flexure or temperature of glass is monitored and the glass is advanced to tempering as soon as a predetermined bending flexure or temperature is reached.

Abstract: A heat treatable sputter-coated layer system for glass substrates may be applied before heat treatment if the layer system includes a metallic layer of nickel or a high nickel content alloy covered by a separate layer of metallic silicon or an oxide of nickel or the high nickel content alloy, which in turn is covered by a protective metal oxide such as stoichiometric Sn O.sub.2.

Abstract: The invention relates to a method and apparatus for bending a glass sheet. A glass sheet heated close to its softening temperature is supported on a ring mould and the glass sheet is allowed to bend by gravity. If necessary, the bending can be assisted mechanically. Air is circulated from a furnace section (1.1) above a glass sheet (7) to be bent into a furnace section (1.2) below the glass sheet so as to produce a different pressure effect on the opposite sides of a glass sheet (7). This pressure effect is used to support the glass sheet which is also heated over its central area to a sufficient temperature for bending and/or tempering, said temperature being sufficiently high that, without said support provided by the pressure effect, the central glass sheet area would bend and sag excessively downwards. The generation of pressure effect can be intensified by fitting the furnace with a ceiling (3) which includes an opening (3.

Abstract: Glass sheets are heated to their heat softening temperature and transferred to a shaping station having an upper vacuum mold with a downwardly facing shaping surface corresponding to the desired shape of the glass sheet. The glass sheet is lifted into engagement with the shaping surface and held thereagainst by vacuum. The mold and the glass sheet are then moved to a transfer station and the vacuum is released to deposit the shaped glass sheet onto a contoured conveying surface which generally conforms to the shaped glass sheet. The glass sheet is deposited onto the contoured conveying surface as it is moving from the shaping station to the transfer station to impart movement in the glass sheet along the contoured conveying surface and minimize marring of the glass sheet as it contacts the contoured conveying surface.

Abstract: A method of and apparatus for establishing a predetermined thermal profile in a glass sheet immediately prior to press bending outside the heating furnace. The press bending members are provided with arrays of heating elements that are individually or zone regulated to assist in establishing an optimum temperature profile in the glass sheet conducive to proper bending. The temperature profile established in the heated sheet by the arrays of heating elements is coordinated with that established in the furnace and subsequently, modified by heat dissipation as the glass sheet advances to the bending station to achieve the proper bending temperature. The heating elements can also be utilized to create a temperature profile in the glass sheet generally higher than that originally established in the furnace.

Abstract: A process for bending glass sheets, preheated to bending temperature, includes passing the glass sheets along a longitudinal trajectory having substantially the form of a cone of revolution in a shaping bed having substantially the form of a cone of revolution.

Abstract: The invention relates to a method for bending and tempering a glass sheet. A glass sheet is supported on a ring mould during the course of heating, bending and tempering and the glass is heated for gravitational bending thereof. After a bending operation, the glass temperature is allowed to decrease to the range of 500.degree.-550.degree. C. throughout, followed by increasing the overall glass temperature to a tempering temperature by heating as quickly and uniformly as possible.

Abstract: The invention relates to a production line for curved panes, in which the panes of glass are heated, brought in a horizontal position into a curving station where they are taken over by curving tools, and then finally conveyed into a quenching station, the stages of quenching and of entry of the glass into the curving station being at different heights.

Abstract: A glass flux composition consisting essentially by weight of 45-65% Bi.sub.2 O.sub.3, 25-36% SiO.sub.2, 4-6% TiO.sub.2, 1-3% Na.sub.2 O, 0.5-2% K.sub.2 O, 2-6% Li.sub.2 O, 0-3% Al.sub.2 O.sub.3, 0-1% ZrO.sub.2, 0-1% BaO, 0-1% CaO, 0-1% MgO, 0-1% ZnO, 0-3% PbO and 0-0.5% CdO is useful for preparing a glaze or enamel composition especially for application to glass such that the composition is then fired in contact with a mould surface or with another glass surface.

Abstract: In a method of and an apparatus for manufacturing a plurality of kinds of glass molding articles, a plurality of processing compartments are arranged in order of processing steps. The compartments have their functions which process glass materials to be molded which are accommodated respectively in a plurality of molds and which are different in processing condition from each other. The function are different in property from each other. Each of the compartments is divided into a plurality of processing chambers having their functions which process the glass materials. The functions of the processing chambers of the compartment are identical in property with each other, but different in condition from each other. The molds remain respectively in the processing chambers for a predetermined period of time. The molds are successively moved to their respective subsequent processing chambers to process the glass materials to form the glass molding articles.

Abstract: Molding is effected while pressing pressure is continuously or stepwise controlled so that at the initial stage in which the temperature distribution of a glass blank is not sufficiently uniformized, molding may be effected with relatively low pressing pessure and in a state in which the whole of the glass blank is uniformly increased in temperature, press molding may be effected with the pressing pressure increased. In a press molding apparatus for an optical element, during press molding, the glass blank is press-molded while the pressing pressure is continuously or stepwise varied so that at a temperature whereat the glass viscosity of the glass blank corresponds to 10.sup.21 -10.sup.11 poise, molding may be started with pressing pressure of 10 kg/cm.sup.2 -100 kg/cm.sup.2, and thereafter in a temperature range in which the glass viscosity x of the central portion of the glass blank corresponds to 10.sup.11 -10.sup.10 poise, pressing pressure in the range of 10.times.(10.sup.11-x)-100+10.times.(10.sup.

Abstract: Disclosed is a material for a tempering process of glass plates utilizing a so-called contact process. It proposes a material with a base of an arrangement of thin metallic threads exhibiting a heat resistance on the order of 0.25.multidot.10.sup.-3 to 2.5.multidot.10.sup.-3 m.sup.2 .multidot.K.multidot.W.sup.-1 intended to be inserted between the cooling plates and the glass of a contact-tempering installation. The process makes it possible to temper glazings sufficiently so that they are used as automobile glazings and the durability of this thread-based material is compatible with an industrial usage.

Abstract: A method of making a curved glass surface with a solar panel formed thereon. A window for an automobile, especially for a sunroof is formed by heating a glass sheet from 500.degree. to 600.degree. C. A transparent electroconductive film is then formed on one side, such as by a CVD method and bending the sheet with the film after heating the temperature from 580.degree. to 650.degree. C.

Abstract: A glass sheet is transferred from a bending cell to a tempering cell on a continuous frame, after which it is held during tempering by discontinuous gripping device. Lifting studs lift the glass sheet above the frame prior to gripping.

Abstract: This invention relates to a method of toughening a glass sheet by heating it to a temperature above the strain point and quenching the heated glass sheet with blasts of air. The heated glass sheet is positioned between two oppositely arranged blastheads, each of which has a plurality of first nozzles and a plurality of second nozzles. The first nozzles are connected to a supply of compressed air, and the compressed air is forced to rapidly expand so as to produce a shock wave and have a first predetermined pressure at the exit of each of the first nozzles. Simultaneously, cooling air is supplied from a blower to the second nozzles so as to have a second predetermined pressure, which is higher than the first predetermined pressure, at the exit of each of the second nozzles. The difference between the second and first predetermined pressures is not more than 0.05 kg/cm.sup.2.

Abstract: A high-convection gas jet nozzle section for a sheet-like material guided over rollers, in particular for thermal prestressing or tempering of thin flat glass sheets, comprises a lower nozzle field having nozzle ribs disposed centrally parallel between the rollers and provided with nozzle apertures and an upper nozzle field of which the nozzle ribs provided with nozzle apertures are arranged symmetrically to the vertical axis of each respective lower nozzle rib; the nozzle bottoms of the upper nozzle ribs have the cross-section of a letter "M" extended by a center strip; the width of the nozzle bottom of the upper nozzle ribs is greater than the horizontal distance between the rollers and smaller than the roller pitch; the center strip and the two upwardly tilted inner legs of the upper nozzle bottoms are provided with nozzle apertures; and the smallest distance of the upper nozzle ribs from the upper side of the material is greater than the smallest distance of the lower nozzle ribs from the lower side of th

Abstract: A method for bending glass sheets is disclosed in which a heated glass sheet (12) is introduced between spaced lower and upper bending platens (16,18). The glass sheet (12) is moved in one direction between the spaced lower and upper bending platens (16,18) during deformation of the platens (16,18) which forms the bent shape in the glass sheet (12). Movement of the glass sheet (12) in the said one direction is continued for at least 1/2 second during a subsequent cooling phase to initiate a freeze in the surfaces of the glass sheet (12) which thereby eliminates mechanical distortion in the formed glass sheet associated with interrupting the movement of the glass sheet (12) prior to cooling.

Abstract: Glass plates for a laminated glass are bent and strengthened by provisionally shaping by heating two overlapping glass plates placed on a deadweight bending mold having a shaping surface by elevating the temperature to a temperature capable of bending glass and by locally heating side portions of the two overlapping glass plates to be deeply bent at a higher temperature in a heating/pressing stage so that the two overlapping glass plates are provisionally shaped by their own deadweight into a shape substantially corresponding to the shape of the shaping surface of the bending mold, pressing a portion of the two overlapping glass plates to be deeply bent from the top by a pressing member after the provisional shaping step in a heating/pressing stage, separating the two overlapping glass plates from the bending mold by pushing up the portion of the glass plates other than the deeply bent peripheral portion of the two overlapping glass plates thereby cooling the peripheral portion of the glass plates in a periph

Abstract: A device for air-tempering, optionally associated with bending of glass plates includes a covering made of a metal fabric and exhibiting a thermal conductivity less than 3 and preferably less than 0.2 W.M.sup.-1.K.sup.-1. It has utility for coverings of frames intended to carry glass plates during their tempering and/or their bending and/or their transport.

Abstract: The invention relates to a method and apparatus for manufacturing a bent glass sheet. A glass sheet (9) carried by rollers (7) included in a furnance (1) is transferred onto rollers (8) of a bending mould (10) included in a mould station (3) built as a part of the furnace. By adjusting the position of rollers (8) of bending mould (10) in vertical direction a glass sheet is bent to a desired curvature while heating it in furnace mould station (3). The roller mould (10), along with its bent glass sheet (9'), is carried out of furnace (1) and into a chilling station. When using a transferable and adjustable roller mould (10), the apparatus does not set limitations for the size or degree of bending of glass sheets to be bent.

Abstract: A glass bending and tempering apparatus including a bending and tempering section, a deformable glass support device and a device for quenching a glass sheet is disclosed. The deformable glass support device is deformable from a substantially flat configuration to a configuration having a desired curvature. The device for quenching a glass sheet is conformable to the curvature of the support device during deformation of the support device. The apparatus also includes a mechanism for blowing air that is vertically movable relative to the support device.

Abstract: Flame seaming a glass sheet of irregular outline using a ring-type burner having an apertured inner wall aligned with the central portion of the glass sheet edge develops an edge of more uniform appearance when the application of a fuel mixture to a portion of said apertured wall facing the glass edge is different for curved portions of the wall facing curved portions of the glass sheet outline than to straight line portions of the wall facing straight portions of the glass sheet outline. Further reduction of non-uniformity of glass edge appearance may result from providing orbital motion between said glass sheet outline and an apertured inner wall of said ring-type burner.