DE1928005C - Method and device for the manufacture of a wired glass ribbon - Google Patents

Description

The invention relates to a method of manufacture of a glass ribbon with a wire insert and is based on a process in which the melting-HUssiges Glass is poured in a controlled amount onto a bath of molten metal such as tin, on which it spreads out to form an evenly thick layer that floats on the tin and is cooled while regulating the temperature along the tin bath.

This well-known method, which is also known as the "float method", makes a difference fundamentally differ from the known processes by which wire glass ties were previously manufactured became. Because of this fundamental difference, it is not possible to produce the Wire glass tape to transfer known measures and devices to this new process.

The invention is based on the known advantages of the float process for production to make use of glass ribbons with a wire insert and to modify the float process in such a way that that the continuous production of a wire glass ribbon is made possible with it.

The inventive method is characterized its basic idea according to the fact that the spreading on the tin bath glass layer is brought at a temperature of about 1050 ⁰ C to the final width of the glass ribbon that at this temperature of the upper surface area of about 1050 ° C from the top ago a wire insert is introduced into the glass layer without the glass surface being brought into contact with the devices for feeding the wire insert, and that the upper surface of the glass ribbon after the wire insert has been inserted so much heat is supplied that the incisions caused by the wire insertion merge again to form a flat surface.

It was found that the temperature of the glass melt at the moment of the introduction of the wire insert must not be below 1050 ° C. The viscosity of the Glass so high that the introduction of the wire insert into the middle of the glass layer is relatively high Forces are required. However, the associated pressure on the glass ribbon makes it the base displaced forming liquid tin at this point. As a result, the glass ribbon gives way, and the for the correct introduction of the wire insert required constant altitude is no longer guaranteed. If only a thin layer of liquid is provided at this point, this can even be so be displaced far that the glass ribbon comes into contact with the solid base, which leads to damage the lower surface leads.

These difficulties are avoided if the upper surface of the glass layer at the moment is not less than the introduction of the wire insert a temperature of 1050 ⁰ C. At this temperature the glass still has a relatively low viscosity and the glass ribbon lull sit II is not stabilized. When producing a Uralit glass ribbon, however, after the wire insert has been moved around, the width of the glass layer must no longer be changed, because this would lead to undesirable relative movements between the wire insert and the glass mass. As a result, it is necessary to bring the glass layer to its final bandwidth at this TVmniM-ntnr of 1050 ° C. For this purpose, it is limited laterally and the. Glass layer ro guided between these boundaries until the glass ribbon has stabilized sufficiently,

Another feature of the invention is that the wire insert is inserted into the glass mass that the devices that guide and support the wire insert do not interfere with the glass surface Come into contact. Any contact with the glass ίο surface leads to impairment the surface of the glass and must therefore be avoided. According to a preferred embodiment of the new process, the lateral boundaries of the glass layer by delimitation body from

Glass is formed from a difficult-to-wet material such as graphite.

Advantageously, at the boundary layer-glass boundary layer, the gluing of the Glass preventive gas layer or a layer of

ao liquid tin can be generated and maintained.

The method according to the invention can be according to

Realize a preferred embodiment practically in the way, and there is another Feature of the invention that the glass ribbon at least

As in the area in which the temperature of its upper side is about 1050 ⁰ C, cooled more intensely on its underside, thus creating a colder bottom layer with increased viscosity, and that the wire insert is pushed into the glass layer from above. This colder bottom layer with increased viscosity gives the glass ribbon overall greater rigidity, so that it is not so easily pressed into the tin bath under the effect of the pressure forces when the wire insert is inserted, but rather offers greater resistance. On the other hand, the colder soil layer has the task of making it more difficult for the wire insert to penetrate further inside the glass layer from a certain depth and thus the wire

To force the insert into the desired height within the glass layer. So here is the height the wire insert, among other things, by the thickness of the colder soil layer, d. H. so by the measure of Cooling determined.

Finally, a more strongly cooled and therefore more rigid soil layer also has the advantage that the entire glass ribbon is given greater strength and thereby the risk of distortion, for example of constrictions under the effect of the tensile forces prevailing in the glass layer is reduced. The glass layer is cooled by the liquid tin. Here is expediently a created transversely under the glass layer extending zone in which the temperature of the tin is regulated can be. For example, the tin bath can be formed by partition walls that extend below the bath surface can be divided into several zones. However, it is also possible without dividing the tin bath container in the area of the Dnihteinfühning zones of liquid tin at a lower temperature to resound by adding more heat to the tin in these zones withdrawn and possibly cross-currents within of the tin bath or the inherent cross currents are increased, which the Uniformize the temperature of the tin.

In the area in which the wire insert is introduced, for the reasons already mentioned, the Surface temperature of the glass ribbon 1050 ° C not

fall below. On the other hand, it is possible under certain circumstances, the threats at slightly higher temperatures to be introduced, but the temperature increase is also limited by the fact that, as above orwilhnt, undesirable at higher glass temperatures Reactions between the wire and the glass mass can occur. The maximum permissible temperature depends on this largely depends on the wire material used in each case and is easy to test through experiments determine.

Since the DruhlzufUhrungsvorrichtungen must not come into contact with the oil surface, the wire insert is not supported on the last part of its way. When the first embodiment of ErFmdung into _E is esch above, according to the glass layer, which means that the longitudinal wires are subjected to compression and buckling. In order to give the wire insert the stiff wedge necessary for this, it is advantageous in a further development of the invention to cool the wire insert until shortly before it penetrates the glass layer. .

It is also important that the wire insert is opposite the glass layer shows a certain "lead" in that it moves at the same speed as the Glass layer is slightly ahead of this. Otherwise tensile forces can be applied to the wire insert Impact, which may be a flawless Prevent the wire insert from being inserted into the middle of the glass layer.

The height of the wire insert within the glass layer can be influenced not only by changing the cooling of the bottom layer and by changing the lead of the wire insert with respect to the movement of the glass layer, but also by changing the angle at which the wire is inserted into the glass layer. The distance between the wire feed device and the glass layer and the temperature of the wire at the moment of insertion also have a certain influence. The optimal conditions can easily be determined by experiments, the surface is so porous that nil3sige & Ziniη can be pumped through, that on " ^w " ^ "" ft "of the threshold a coherent ι u over which the glass band slides.
Even with these Ausftllmingsformcn ^u process, it may be expedient to ^ÜUb J; ^. in the region of distraction '* "flat on its underside versturKi to''*''· can from seincr ™» ^b I to the above-described advantages ium. Use the same method can be applied before and directions as imι .β first mentioned Ausfühnmgsfor.n beKhncDensin ^ After the introduction of the wires '"J ⁰ B ^'" £ surface of the glass ribbon «^ anglüufg« 5, which through the dosed ^wu ii side of the glass ribbon to the
be brought. At d.escr
Glass ribbon it can ^ "
similar to the area of
* o Temperature gradient ™ within * r U right, ie a kdlttrt uoü

to keep. v.rf..lin-η im insofar as well

The inventive method · t ™ ^L '™ ^

particularly advantageous as de DwJJ '^ g ⁸ J ^ a ₅ in vo hg "" nrtomreiir ^ jeremto At sphere introduced into the glass we "J""'. _h any risk of corrosion, al do" ^ «« £ « avoided, and only the chrome wire ends can be used

Possibly present ^α ' ^ιϋε ^^ Χ; ^Χ / · ^ οΓ ^ Μη tin baths are made by the: Atmo ph. e ubur ^ reduced, so that de DrdliteiiiLiy. cm

Appearance "JaIt procedure and

Further characte. d η .uu »Vjrtanr preferred version of ur u

Guide suitable Υ ° " ^ΐϋ ' ¹ ""^" j ^, "Figure"' describe ^ Dc «« * ■ «™ _thner

Fig. 1 ^{and 2} ^ ^e f ^e _{V ()} "S _r aht float glass im

^ ne another embodiment of the method according to the invention is characterized in that Fi g. 3 and ^ one, second
such hunting ^^

Se? Abing to below the top of the glass ribbon can be lowered without it coming into contact with the glass surface and that the wire insert through the glass ribbon m the glass layer is drawn into it.

In the practice, for example, possible to proceed so that the glass ribbon across a u, Xn ^g -glr hlÄuc1nu £ "on the Stel.e the ₅ o D ^ ujmng" md, m ^ ^

Fig 8 erne Ainv JJ t _behind the wire rack I cttn Λ swo.d _b

^^^^ systems common, that will

Meltable glass 1 is poured over a suitable outlet I 55 melted glass is 111d t. The

j ^ j ^^^^ l ^^ stretched

organ protrudes. .

Another possibility for practical

guidance consists in pulling the glass ribbon over an in Transverse direction of the tin bath immersed in this

_wi p _il2 | _uiu i> cisielHlitli is, are in the

W e .js F _fc; ^ "Hl _{zimibaiIce zll beillcil}

Bt ^ -ichjn J. , ^^ _{einetillldltc}

Suteii dtr uiaν _{hlct dic the} glass

2i ^

, "" "

5 6

with a central opening 6, through which the cooling beam 41 lies below the level of the tin bath A coolant passes through the feed lines 7 and ensures the necessary cooling of the tin pipes so is the temperature of the boundary layer between this cooling beam and the glass body to a height at which the glass tied. The chilled beam points upwards at the side does not stick to him. 5 extending approaches 42 that perform the function of the

The delimitation body 5 can also take over from a porous delimitation body. The tubes 43

Graphite, and through the central off- ensure the supply and discharge of the cooling

openings 6, protective gas or liquid tin can flow to the cooling beam. Like the limiting

be passed through, the on the surface, against the body 5 can also the cooling beam 41 with the attachment

the glass layer rests, expediently also made of graphite through the pores of the boundary sets 42

tongue body emerges and forms a film here, which or are made of carbon.

the smooth sliding of the glass layer on the guide body 20, 21 for the wire insert

Limiting bodies favored. are expediently in their height and in their

The area 3 B of the tin bath, mounted adjustable above its inclination. For this purpose, the wire insert 10 is inserted 15 into the glass layer 11, as Fig. 5 shows, the arms 50, on which the cooling is carried out, has a lower temperature than the body 20, 21 are attached, at the lower ends area 3 A . to the tin in this area two spindle poles from 51.52 to 53 and 54 cool are rotatable supported within the bottom of the container. The spindle rod 52 is arranged in a fixed cooling tube 2. Furthermore, as shown in FIG. 2, the bushing 55 is guided. With the help of the hand shows, laterally outside the delimitation body 5 20 wheels 56 and 57, the height and inclination of the cooling tubes 13 can be immersed in the tin bath, and the guide body can be adjusted as desired.
The tin bath tank is deeper in the area 3B. The feeds are also formed on the arms 50, so that they can be supported for rolling 22, 23 if necessary. While the roller 22 sits in moderate cooling favorable cross-currents in this one fixed bearing, the roller 23 is able to amplify senses. Furthermore, for separation 25 at the end of an oscillating pivot mounted rotatably at 59, the more strongly cooled area from the neighboring lifts 60 is arranged. A counterweight 61 is seated on the other arm of the zone on both sides of the area 3 B to shortly rocking lever 60, whereby thresholds 14 reaching below the level of the tin bath provide the necessary contact pressure for the roller 23. will create.

Above zone 3 / i is the wire feed 30 The wire feed bodies 20, 21 are hollow.

device arranged. It comprises essentially formed and flowed through by coolant that flows through

two to just above the surface of the glass ribbon, the lines 27 are supplied or discharged. the

Reaching guide body 20, 21 for the wire cooling is used, among other things, the wire insert

insert, one above this guide body on its way to penetrate the glass

arranged pair of rollers 22, 23 to cool the wire insert 35 and thereby

given the necessary feed and to give the wire guides the necessary rigidity. As in Fig. (I

supply roll 24, from which the twisting sheet 10 rolls off. is shown, the guide body on their

If necessary, further guide rollers 25 can have outer surfaces or at least on their lower ones

on the way of the wire insert from the supply roll ends have a thermal insulation 65, which against

up to the pair of preschool students 22, 23 is also useful in order to avoid too much intensity

which may be provided with projections Cooling of the glass ribbon surface through the guide

that intervene in the mesh of the wire netting, which is relatively close above the glass

imil ensure that the cross wires are properly aligned. surface ends to prevent.

The Fülmingskkörci 20,21 can be over the pipe with the help of the device described

lines 27 supplied with coolant. 45 not just a one-way network consisting of a wire

So that the entire facility for the wire layer, but possibly after minor

Feed is as accessible as possible, one of a plurality of amendments is also available

In the embodiment shown in Fig. 1, the ceiling 28 parallel individual wires existing wire insert ir

of the tin bath container interrupted and through which the glass layer are introduced. For this purpose

vertical walls 29 and the gas-tight metal 50 are only the two Fühningsktfrncr 20 21

housing 26 created a space in which the media by one of the number of individual wires!

Mixing V01 directions outside the actual number of double-walled fiilinincsrohrcn replaced

Zinnbadhchiiltcrs are arranged. which every single wire in front of the finleitunc in di <

Glass layers are supported above Beieichcs 3C of the tin bath.

below the ceiling 30 of the tin bath tank clck- 55 The arrangement shown in Fig. 7 has aussc

Irish heating elements 31 arranged, the power of which the actual Drahtzuführuimsoigan 21 zwc

i jrii Afd further similar arranged at a distance from this

fb

g g gn wire feed soigan 21 zwc

is and the jcwrilip.cn requirements nn- further, arranged at a distance from this similar

is fitted. built up organs 70, 71 on these form cini

The Vorsehubwal / on 22. 23 are, as in Fig. 2 slot nozzle, through whose mouth Sritutzuns on there It is shown that a glass belt is blown up via a WVlIc34, so <111 It's this one off

Miotoi 35 driven. In the gas-tight (iehousing 26, 36) seal 74 forms. The protective gas muli self-vcr

within which the whale / .npaare feast. t, ensures such a high TcmperaluT hourly that dl

h h dll dß d Obflh d Zbd Glb

gg g he TcmperaluT have, dall dl

I dalili here that the surface of the tin bath Gliisbandobcrfiiche not under the xuPissiue tem nc

not mil dom Snuoisloll the Aultenatmosplilire in ranirgreiizc is cooled, the litl.lt is only cinfnclu

Büh k wise dadh iklih

Touch comes.

Meidci in V \ y, 3 uiuM daigcstelllen

Foim is inside the bath in the circuit through the Sihlit / nozzle cefühi

40 provided Kühlbnlkcn 41 arranged. This whd. Regardless of this, the Diahlcmhi-e ii

p g is cooled, the litl.lt is only cinfnclu

65 Realize wise, that the rubble

gcstelllen Aiislülmings- abosmiiM above the tin bath and through <left

of the one with cooling tubes line 75 in the circuit through the Si'hlit / nozzle cefühi

41 arranged this whd Ubhiii d

the manner described through the cooled guide slot be guided.

By forming the bulge 74, it is possible to lower the wire feed member 21 so far that that the wire insert 76 need not be pushed into the glass 5 layer, but that it can be drawn into the glass layer by the glass ribbon.

The principle of pulling the wire insert into the glass layer can also be used with the method shown in FIG. 8 dar- io provided arrangement can be realized. With this arrangement there is a self within the tin bath 3 transversely across the width of the tin bath extending threshold 80 which is the level of the tin bath towers. The threshold 80 consists of a 15 highly heat-resistant material, preferably of Graphite, and is provided with a central channel 81. The upper part 82 of the threshold 80 is sufficiently porous that the channel 81 allows liquid Tin can be pumped through, which exits through the 20 pores and above the threshold a continuous Tin film 83 forms, which prevents direct contact of the glass ribbon 84 with the threshold 80. The wire feed member 21 only has the task of guiding the wire insert 76. Since the as Wire insert 76 is drawn into the glass ribbon, it is not necessary for the wire feed member to be designed in two parts with the formation of a slot, rather a one-part guide device is sufficient in the manner shown. It is also unnecessary in 30 same way as in the case of FIG. 7 illustrated embodiment, which is shown in FIGS. 1 to 6 shown Guide roller pair 22, 23.

Claims (26)

Claims: 35 1. A process for the production of a Drahlglasbandcs, in which molten glass is poured in a controlled amount onto a bath of molten metal such as tin, on which it spreads to form an evenly thick layer, which moves floating on the tin and under control of the temperature along the Tin bath is cooled, characterized in that the spreading glass layer on the tin bath is brought to the final width of the glass ribbon at a temperature of about 1050 ° C, that at this temperature of the upper surface of about 1050 ⁰ C from the top a wire insert is introduced into the glass layer without the glass surface is brought into contact with the devices for feeding the wire insert, and that the upper surface of the ginsband after the wire insert has been inserted so much heat is applied that the incisions caused by the wire insert become one plan surfaces merge again. 2. The method according to claim 1, characterized in that the SchmclzflUssige glass after pouring onto the tin bath at least up to a temperature of about 1050 ° C is guided between lateral boundaries. 3. The method according to claim 2, characterized in that the lateral boundaries the glass layer by means of limiting bodies from Glass difficult to wet material like graphite be formed. 4. The method according to claim 1 and 3, characterized characterized in that at the boundary layer the delimitation body - glass a layer of glass preventing the glass from sticking or a layer of liquid tin is created and maintained. 5. The method according to one or more of claims 1 to 4, characterized in that the glass ribbon at least in the area in which the temperature of its upper side is about 1050 ° C is, cooled on its underside and thus a colder soil layer with increased Viscosity is created, and that the wire insert is pushed into the glass layer from above will. 6. The method according to claim 5, characterized in that for cooling the glass layer below the area of the wire inlet flows of liquid tin with lower Temperature can be generated in the transverse direction of the tin bath. 7. The method according to claim 5 or 6, characterized in that the Drahteinlagc with the same speed with which the glass ribbon moves, but with maintenance a certain "advance" is pushed into the glass ribbon. 8. The method according to one or more of claims 5 to 7, characterized in that the wire insert until shortly before it penetrates the glass layer to avoid buckling is supported on both sides by suitable guide devices as a result of the compressive stress. 9. The method according to one or more of claims 1 to 4, characterized in that the glass ribbon at the point of introduction of the wire insert while maintaining its support locally distracted so far from its transport level on a layer of liquid tin is that the wire feed member with respect to the level of the glass ribbon at the highest point this local deflection can be lowered to below the top of the glass ribbon, without it coming into contact with the glass surface, and that the wire insert through the glass ribbon is drawn into the glass layer. 10. The method according to claim 9, characterized in that across the glass ribbon coherent hot protective gas flow is blown onto the glass ribbon and thereby untei Local partial displacement of the liquid tin creates an indentation in which there! Wire feed member protrudes, 11. The method according to claim 9, characterized in that gc indicates that the glass ribbon is immersed in the tin bath in a transverse direction and the swell towering over the tin bath through which the glass ribbon locally forms an upwardly directed bulge, wobc the threshold on its surface protruding from the Zinnbadsptegi is so porous that Liquid tin can be pumped through a central channel which is placed on the obci surface of the threshold forms a coherent tin film over which the glass ribbon slides. 12. The method according to one or more of claims 1 to U, characterized in that the Drnhtcinlage is cooled until shortly before its Hindringe in the glass slide . 13. Float glass system for carrying out the method according to claim 1 to 3, characterized by in the melting range of the glass down to at least about 1050 ° C, immersed in the tin bath, provided with cooling devices, lateral delimiting bodies (5; 42) made of heavy glass wettable material such as graphite, by a wire feed device (20, 21, 22, 23) arranged above the tin bath and by heating devices (31) arranged downstream of this above the glass ribbon. 14. The device according to claim 13, characterized in that the upper cover (28) of the tin bath container in the region of the wire feed device (20, 21) has a recess and that the transport and guide devices (22,23,24,25) for the wire insert is arranged within this recess formed by the vertical walls (29) and by the ceiling stones that are more strongly lowered onto the tin bath than the other ceiling stones (30) and are thus accessible without opening the tin bath itself. 15. The device according to claim 13 or 14, characterized in that the lateral delimiting bodies (5, 52) are made of porous graphite and have a central channel (6) into which protective gas or liquid tin is introduced which is graphite at least at the interface. Glass emerges and facilitates the sliding of the glass ribbon on the boundary surfaces. 16. The device according to one or more of claims 13 to 15 for performing the method according to claim 5 or 6, characterized in that approximately below the wire feed device tubes (12) through which coolant flows and / or immersed in the tin bath (3) Cooling tubes (13) are provided. 17. The device according to one or more of claims 13 to 16 for performing the method according to claim 5 or 6, characterized in that below the wire feed device a completely immersed in the tin bath, extending transversely below the glass ribbon to the lateral delimiting bodies (42) , cooling beam (41) traversed by channels (40) through which coolant flows, preferably made of graphite. 18. Device according to one or more of claims 13 to 17, characterized in that that the tin bath is divided in its longitudinal direction into several zones which can be regulated independently of one another in terms of their temperature. 19. The device according to one or more of claims 13 to 18 for performing the Verfalirens according to claim 8, characterized in that the wire feed device for a reticulated wire insert (10) from two spaced apart and thus forming a passage slot for the wire mesh forming coolant-flow guide bodies (20, 21) and a driven pair of feed rollers (22, 23 ) arranged above these guide bodies (20, 21), which inevitably push the wire mesh (10) into the glass ribbon at the transport speed of the latter. 20. Device according to one or more of claims 13 to 18, characterized in that the wire feed device for a wire insert consisting of a plurality of parallel individual wires consists of a number of cooled guide tubes for the individual wires corresponding to the number of individual wires and a pair of driven feed rollers arranged above these guide tubes (22, 23) for the individual wires. 21. Device according to one or more of claims 13 to 15 for performing the method according to claim 9 and 10, characterized by one parallel to the wire feed member arranged, with its mouth on the glass ribbon directed slot nozzle and means through which Protective gas, preferably hot protective gas from the tin bath tank, introduced into the slot nozzle will. 22. Device according to one or more of claims 13 to 15 for performing the method according to claim 9 and 11, characterized by a transverse to the glass ribbon within the Tin bath arranged and its surface slightly protruding threshold with a central Channel and a porous upper part as well as devices for continuous passage of liquid tin through these pores. 23. Device according to one or more of claims 13 to 22, characterized in that that at least the lower end of the guide body (20, 21) or the guide tubes in the Direction of movement of the glass ribbon is inclined. 24. Device according to one or more of claims 13 to 23, characterized in that that the guide body (20, 21) or the guide tubes are adjustable in height and / or inclination are arranged. 25. Device according to one or more of claims 13 to 24, characterized in that that the guide bodies (20, 21) at one of its ends (S3, 54) are vertically adjustable Spindclstangen (51, 55) mounted arm (50) are arranged. 26. Device according to one or more of claims 13 to 25, characterized that the leaders on their outer surface! with Wlirmcisolationskkörcrn (65) are given away. For this purpose 2 sheets of drawings