DE1950006A1 - Heat treatment furnace - Google Patents

Description

DR.MÖLLER-BOR ^ DIPL-ING. GRALFS DIPL-PHYS. DR. MANITZ DIPL.-CBEM. DR. DEUFEL

PATENT LAWYERS

Munich, October 3, 1969

Our reference: Fs / wi - G 2020

Glaverbel

166, Chaussee de la HuIpe

Wat ermael- ~ Bo i t sf ο r t

Belgium

WlEMEBEHAlSiDLIMGSOi ¹ EGG

The invention relates to a furnace with at least one Wall made of fire-resistant blocks, hereinafter referred to as the annealing furnace.

Building annealing furnaces from refractory blocks requires with the current practice for a relatively long time, especially when the blocks are individually attached to the one carrying them Frame, i.e. the frame structure or a metal wall Need to become. If such an annealing furnace has a melt pool with a greater density than the refractory To accommodate blocks, these blocks must be firmly v? Ranfcertr to avoid that they are due to the buoyancy forces from their holder. This is particularly the case for annealing furnaces in which the weld pool consists of a Made of metal. In order to ensure that the fire-resistant blocks are held in place, it has already been suggested that these

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aHAUNSCHWi-LS. tA »CISGiSPAitK, 8, ΪΕΙ. {0531} 28487 si f.sSKCHEN 22, SOBER? KfSCH-STPAtSg ΐ, TEl. (OBII) 225110

1S50006

'to be provided with one or more recesses in which An anchoring element, e.g. a cleat or an anchor bolt, can be used, which is then inserted in the recess with a fire-resistant material. The protruding ends of these anchoring elements are attached to the framework e.g. connected by welding or stealing.

This type of attachment has the following disadvantages. The bonding material between the refractory blocks and the anchoring elements is a dangerous place, the unfavorable working conditions is subjected especially by the influence of heat, increased wear under W. If any of the refractory blocks become detached from the anchoring, the furnace structure is exposed and can be severely damaged from direct contact with the furnace contents, for example the molten metal. This situation can arise, for example, in an annealing furnace in which tin is used as a molten bath and in which the tarpaulin is processed using the floating glass process or the floating annealing process.

Even after the fastening der_ fire-resistant blocks on which ^ truss structure of the furnace, it is still not completed because usually the by-thermal behavior must be installed in a control that contains, * which typically components which have to be arranged within the furnace. These components run through the furnace walls, and their installation therefore makes it difficult, since it is hermetic. Waterproofing is required. In the special case of a floating annealing furnace, the atmosphere inside the floating annealing tank must be carefully isolated from the outside atmosphere in order to prevent the molten metal from being oxidized and thus deteriorating the surface quality of the glass ribbon formed on it,

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The invention is therefore based on the object of overcoming at least some of these disadvantages.

Based on the annealing furnace mentioned at the beginning, this object is achieved according to the invention in that at least one Wall of the annealing furnace is formed at least in part from a refractory block which has a passage for a flow medium and that the passage is interspersed with at least one element £ with which the block is in its Bracket is anchored.

These features of the invention allow in an advantageous manner, while reducing the working time required for this To simplify the construction of an annealing furnace considerably. Besides that there is no need to use a sealing material to produce a reliable connection between the anchoring element and the fire-resistant. Block.

An advantageous development of the invention consists in that at least one wall of the annealing furnace is at least partially made of a plurality of assembled and fire-resistant blocks is formed which have a passage for a flow medium, and that the passage of. at least one element is penetrated, with which the 31öeke are anchored in the holder. Based on these characteristics, the structure of a Annealing furnace particularly simplified.

The fire-resistant blocks can, in a simple manner, e.g. by Giesser., with a cavity that receives the anchoring element and as a passage for a circulation medium serves. Deviating from this, the required Cavity can also be carved out of a solid fire-resistant block after its manufacture.

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BATH ORIGINAL

The walls of an annealing furnace can be constructed from a variety of refractory blocks or an array of blocks are, according to the invention of the anchoring element transversely are interspersed. For example, the bottom of the annealing furnace can be made from a There are a plurality of such block arrangements which are arranged next to one another and which extend across the furnace.

If desired, one or more fire-resistant blocks can also be poured onto an anchoring element and form a unit with it. This is particularly beneficial if the refractory blocks and the anchoring element are not subjected to very high thermal expansion. The construction of the ™ annealing furnace can also be simplified by screwing the individual blocks onto the anchoring elements or screwing the anchoring element into the blocks. According to the invention it is also provided that there is a substantial distance between the walls of the cavity and the anchoring element. It is therefore not essential that the anchoring element or the anchoring elements completely prevent movement of the block or blocks. It is sufficient if the anchoring element or the anchoring elements merely prevent the block or blocks from shifting out of the correct position within the structure. Of course, the blocks can also be held in place by additional devices, such as a refractory binding material, but this is not absolutely necessary due to the anchoring elements used. ^;

The construction of an annealing furnace wall can be particularly accelerated by using block arrangements, since it is made of no need to customize every single block on that To attach the framework of the furnace. In individual cases it is sufficient if the arrangement is simply at the front ends is anchored in the furnace structure. '.

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Each individual block or the arrangement of the blocks can in the framework by anchoring the ends of the anchoring element es "or the anchoring elements are held. When using bloek arrangements of considerable length connecting elements can be provided between adjacent blocks and the furnace structure, which form the anchoring element or hold the anchoring elements between the ends of the assembly. Of these connecting elements are only few required, even if the block arrangement is relatively is long · In the cone it is enough to have a single fastener proceed in the center area of the block arrangement «

The invention also offers a further significant advantage, by the fact that the thermal conditions can be controlled with the help of a medium that is at least through one Cavity of the block or blocks is performed. The blocks can be provided with corresponding cavities it is possible that the anchoring elements are in the same cavity are provided, the cross-sectional dimensions being kept in this way be that the medium between the anchoring ^ element and can flow along the wall of the cavity ©. at Another embodiment can be the passage for the medium from dam penetrating the cavity anchoring element be formed itself, which is tubular and used as a conduit for the circulation of the lur control of the th @ rmisohtn Conditions used medium is used, line The line does not necessarily have to cover the entire length The length of the block or the blook arrangement run »With the Line © of the dtm passage devices can also work together, di <a allow the. Tax University of Thermal Conditions; at certain broadcast points in the block or occurs in the blook arrangement, or that a, dif-fe.ren.tie.lle Control is possible. This means that g.B »is the setting for the temperature in the floating annealing tank both lengthways and

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in the transverse direction according to the desired temperature are possible. At least one of the cavities or the passages is provided with elements for differential thermal Control provided., Which can for example consist of heat insulators, which at locally limited places - the cavity or the Provide line within the block or the block arrangement are. For thermal control, electrical ones can also be used Resistance devices and / or cooling devices within the cavities are arranged.

The invention also relates to a method for controlling the ^ thermal behavior of the inner surface of at least ™ a part of a Glühofenwand wherein erfinduhgsgemäss is provided that a medium is conducted through a passage or a plurality of passages whose temperature or substantially v ^ of of the adjoining interface of the passage or the passages is different in order to define a thermal behavior which is substantially unequal over the length of the passage or the passages. Advantageously, significantly more heat is transferred in the central area than in the edge areas of the furnace wall. In a floating annealing process, in which molten glass flows onto a melt and cools down, it is particularly advantageous for the sole, the floating annealing tank, if this is thermally controlled by a circulation fluid that causes uneven cooling over the length of the passage or the Causes passages.

In a simple embodiment, there is the facility for thermal influence at least from a line that is formed by the anchoring element. With another Variant, a line is formed by an anchoring element, the -from a leading the circulatory fluid There is pipe that extends over part or all of the length of the block or the block arrangement. Such a one

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Line can be designed in the form of a needle curve, if a differential influence of the thermal conditions is desired. .

In an advantageous embodiment “there is a passage In the block or in the block arrangement of a circulation line which extends over part or the entire length of the Block or the block arrangement extends and with outlet. Openings for the circulation medium is provided. .For a differential control can be the distance of the outlet openings along the drilling axis from the face of the block or remove the block arrangement from towards the center, so that in the center of the block or the block arrangement more Heat can be removed than at their end faces, moreover, the tube provided with openings can comprise at least one displaceable Siemens in the form of a sleeve, which the outlet openings is able to cover and with; the the Amount of immgen by the Cf. , escaping medium controlled be ka: m.

Through this thermal control, the temperature of the fire-resistant Blocks and their behavior can be controlled; omitted or at least the number of such devices reduced. This is especially important when the inside of the aluminum stove is sealed off from the outside atmosphere should be, as is the case with a glass floating glow furnace the case is. In particular, in the case of a floating annealing furnace for the control of the thermal conditions the cavities in one or more of the refractory blocks instead of cooling devices that are usually used over the glass ribbon are arranged. This gives rise to an important one Vor-ceil, as the cooling acting on the glass from above only in a limited way. Scope isr possible to the occurrence of Glass defects in the form of waves or broken lines

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BATH ORIGINAL

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to avoid which the optical quality of lengthways : production of thin-drawn glass is severely impaired. A consequence of one Such limited cooling is the tendency to form glass-like drops, which are completely different. Composition compared to that produced by the swimming process Have glass, and which is on the inner surface of the refractory blocks due to a vitreous structure form within the block, rise through the melt and drawn into fine fibers between the refractory blocks and the floating glass. The arrangement of the elements influencing the thermal conditions in at least some of the elements running across the blocks.

ψ Passages eliminate the need to provide thermal control devices within the tin melt. The establishment of such elements within the melt is a major disadvantage, since the drilling required for this has to be made from a special material because of the required resistance to erosion and, moreover, the melt must be substantially deeper in order to accommodate the control devices. If the control of the thermal conditions is achieved with the aid of a cooling medium which penetrates at least one passage in the blocks, the temperature of the tin melt can easily be adjusted in the longitudinal and transverse directions and the annealing tank can be shortened. The cooling can be greater in the longitudinal direction along the central area, so that a

'Compensating heat supply ah the edge areas to avoid excessive undercooling of the glass ribbon can be dispensed with.

Although it is intended that the blocks are based on an arrangement a single anchoring element, it is also possible that two or more such anchoring elements run through the fire resistant blocks. If this is the case, the cross-sections of the anchoring elements be smaller than when using an anchoring element. This means that the cross-sections are also borrowed

00 981 5/1 UG

Cavities smaller, which means one less mechanical Weakening of the blocks achieved.

At least one anchoring element is advantageous in a block or a block arrangement in the form of an angle iron executed. The cross-section of the angle iron can, for example, be U-shaped or diagonally cross-shaped. For the sake of customization on the angle iron, the cavity in the block can be designed in such a way that between the individual legs of the One or more passages through which the circulation medium is passed. That way you can the circulation medium come into direct contact with the fire-resistant block. Leave the block or blocks also hold themselves in place in a satisfactory manner by the angle iron. For example, a U-shaped bent angle iron a block with a rectangular The cavity is held particularly well because, for example, the base of the U-shaped angle iron is against one wall and the two thighs against the other two walls of the cavity which prevents the block from resting on the anchoring element tilts or rotates.

Instead of an angle iron as anchoring element, as already mentioned, a pipe can be used. The pipe can have a self-contained wall, so that the circulation medium can flow therein without coming into contact with the fire-resistant block or blocks come. This design is always necessary when the circulation medium comes into contact with the fire-resistant Blocks should be prevented. This feature is beneficial when a ingot is melted at one with the Metal-filled furnace breaks and thus the liquid metal does not enter the system for thermal control can penetrate.

00981 57 UAO

It is not absolutely necessary for the block or blocks to be provided with tubular cavities for receiving an anchoring element. As a departure from this, the: blocks can also be provided with a cavity which is open to one side and preferably runs at an angle in cross-section and The block through which the anchoring element extends can be removed therefrom by sliding it successively in two different directions. In such an embodiment, the anchoring element can first be installed during the construction of the furnace frame and, for example, can be held with its ends on the furnace structure. The blocks are then hooked into the anchoring element. For example, if the intended incision in the block extends L-shaped, the blocks can be suspended in the "anchoring element, by being first moved vertically and then horizontally calibration Tung ^'..:

If with the help of an anchoring element a four of Blocks are attached so it is not necessary that all Blocks of arrangement identically the same and in the same way are connected to the anchoring element. E.g. the End blocks can be cast onto the anchoring element, while the blocks in between are simply cast onto the anchoring element screwed on or hooked into this.

If a block or blocks, which are held on the anchoring element according to the invention, part of the BodenMche one. Form annealing furnace, which is a 'molten material having a greater density than the fire-resistant blocks, at least the ends of the anchoring elements are advantageously attached to the furnace structure. It is also advantageous, especially when the arrangement of the "blocks extends over a relatively long span, a or to provide several fastening elements with which the

00981 57 TUO

Anchoring element is attached to the furnace structure. For example, a fastener in the center of an elongated Be arrangement. When the blocks are poured onto the anchoring element, one or more fasteners, e.g. in the form of stirrups, must be attached to the anchoring element beforehand, so that after completion the arrangement, the fastening element or the fastening elements are embedded in one or more fire-resistant blocks. In deviation from this, the fastening elements also be designed in the form of hooks which are welded or screwed to the anchoring element with one end or riveted, while the other end with the help of a «shoe in a corresponding counterpart to the Oven construction is kept that with the oven construction is preferably schwelsst. In this way, a certain free movement is given for the connecting element, so that it can shift depending on the thermal expansion of the refractory blocks. With another Embodiment are the connecting elements in the form of Made cuffs that grip around the anchoring element and have a shaft with a threaded portion, the is supported in a slot in the furnace structure. In this way, a certain amount of freedom of movement is also guaranteed. It goes without saying that there are also other mounting options can be provided to connect the anchoring element to the Cfen structure.

- Advantageously, the surface of at least one fire-resistant block which can come into contact with at least part of the contents of the furnace, with at least an element clad or covered; which has a thermal Conductivity and / or density; which is greater than that of the fire-resistant block. This is special useful when one or more block arrangements form all or part of the bottom surface of the annealing furnace.

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BATH ORIGINAL

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Such a design can help reduce the thermal To improve the homogeneity of a tin melt and / or to be effective as a load for the refractory blocks, whereby this coating can also protect the joints between two adjacent fire-resistant blocks. Be purely for this purpose preferably tungsten plates are used.

For some applications, layers of blocks, e.g. thermally insulating blocks, between the blocks held by the anchoring elements and the outer furnace frame be provided. As an example of this, for the insulating blocks silicon marl and. for the anchored "Blocks of carbon are used. The carbon blocks serve to dissipate the heat when it is desired that the Heat is to be dissipated from the molten metal to the cooling medium flowing in the recesses of the blocks, on the other hand the insulating blocks provide a high level of thermal insulation for the annealing furnace.

In an annealing furnace according to the invention, two or more Blocks or block arrangements of the type described above can be arranged next to one another, so that they form a part or. form a whole wall of the oven. It is also possible a number of such blocks or block arrangements on top of one another Arrange layers. If in an annealing furnace designed in this way, two or more layers of Blocks are on top of each other, anchoring elements extending through the blocks according to the invention in all or only a part of the layers can be provided. The layer that is used is preferably that which occurs Forces (gravity, buoyancy, etc.) are best suited. is able to withstand. In annealing furnaces with over a large Span extending walls can have at least two blocks or two block arrays facing each other End faces may be provided, these being connected to corresponding anchoring elements.

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1950888

The fire-resistant blocks ltönneii made of a suitable material) ZiBi. Carbon or a siliceous clay be constructed* "

Although the invention is described below for specific use is described for a floating annealing furnace? is this too for other annealing furnaces in the glass processing industry * the Pottery and iron and steel industry recoverable *

Examples of embodiments of the invention are the Drawing shown * ES show

fig * 1 a longitudinal height through a BchwiiMglÜhtarils: \

fig * 2 a lengthways vertical§n feil = cut lengthways dei? iinie Ii = II der: £ lg ~. 3 through the Bödehwahd of the Sch # iTämgiühänlES iii v ^ rgrösseitem measure;

iig ». 3 a vertical section through the boom wall along the ¹ line III-III of fig * 2 \

Fig * 4-6 cuts dent section according to FIG ehtsfrechen * 3 and further through the walls Aüsführungsför'meh eirtes Schwimmglühtanks according to the invention verlaufefi \

Fig * 7-12 different types of fire-resistant blocks and

Ih Figs Ϊ is a series of previously shown lusfuhrUnlsfoim a Cxiäs-Schwiiiiaglüheiniiehg iiä Itängsschhitt därgesteüts This device comprises a Schmei ^ tank I ₄ a floating annealing at 2 "and a tempe:!? Annealing furnace 3 *

The swimming pool is made up of a floor 4, a ceiling 5 ^ Seitehvjähden 6 and St ir h & rändeh 7 »8 built up by the ÖecHe 5 double slots 9> IO are separated * All of these parts des SchvrimmgiüntänKs 2 are made of a fire-resistant material optional * A metal cover 11 encloses the hefme - tisiäii den Bodön 4 $ the side walls 6 and the end walls 7 ^ 8 dös Särllies j who takes a bath of a molten material 12 ~ -

Bäs g§§GMoizöne Q-las from the G-lasbad Ij in 3ciimeizfeäiilt 1 is poured over a © S-ilssligpe ΪΜ- ziwis'Giien Öies'sröllen 15 * 16 ^ P wglöhe eiii Ö-iäs'bänä -1? ' förfiens This Öläsbänd 17 will be södänn

Si-I help one? Ah'uähl m & Transpdftfolleii 18 of the slot 9 'IFFI äentfimmgiiintänis zügeführ't and KöiMt äxif the molten bath of the material "12 Isué liögehi while in the dur'öh the ΈΪ eil.' Söhmelz- λ ängeäeiitetöii Weis'ö weiterUSrsSMben The wirdi on the Bath of the material 12 see shifting glass ribbon v / ies in this way feüeipÖert fiäs melt bath of the material Ϊ2 £ anii from a molten salt ^ but it consists of a metal, like eg egg-thin Silb§r = öä'ör Zihnbädi

',. Iiä Böhwiffimglüntänl v / ifd the glass ribbon in the direction of the ^ Söhliti lÖ versöhöbeh and with Hii-fe v§n roles 19 in one

* s. ■

Ih ägh i? I§s Ά üilä % §ihd V / ähäKöfistfukfi§heh shown ^ those for ä'en aeMriinmglü'htänK geinäss Figs Ϊ Verwönduhg find Köh-

& §L䧧 di ^ sgf * Bäfätiilungeii köiiheii fSüetbästähdige Blöke 31 arranged in rows on a metal wall 31 s§iüj di§ with eili§iii BieMüngs- lind Mnä§mäteriäl 52 bide'ekt Is "is Si§ iteiiien igi feuirbSstäigeii llS§Me 8rstl? Sck§n see in Qüg ^ iöBJüni äuteh den SöhWiffifluaiäiilEä In IeE figs 2 uM

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BATH ORIGINAL

3 int shows a series of these blocks which have a rectangular cavity 34 which each runs through the corresponding block. The end blocks rest on side metal walls 35 »36, which are also covered with a sealing and binding material 37. A. Pipe 33, which is rectangular in cross-section, runs through the cavity of the aligned blocks, with a small amount of free space remaining around the pipe. In this way, the tube 38 represents an anchoring element for the legs of the blocks. The respective end of the xlohres 5 extends through openings 39 and ίΟ in the oeitenwänie: i 35 and 36. Outside the flash annealing tank, the bore 33 is made with the help of fastening elements ^a l and 4.1 held that an axial movement of the tube due to its thermal. Allow expansion. The fire-resistant blocks ^U 6, 47 are attached to the end blocks of the row and lie against the corresponding side wall. 33, ^x '?, At. The blocks. 46, 4-7 together with the blocks ^ form the tank for receiving the molten material 48, on which the glass ribbon ^ 9 floats and slides in the direction of the arrow X.

On the 3iöcKer. ^{Z 'A} of the CJlühtankee are arranged tungsten plates 5 ^, ieren density is larger than the density of the geschmolzer.e :: material 43. These plates 50 also have a higher thermal conductivity than the refractory blocks and wear :, thus the thermal homogenization of the Melt pool - * S at. In addition, these plates also act as ballast for the annealing tank and protect the connecting areas between the individual fire-resistant blocks 33

Inside the pipe 33 is a circulation line 43 for arranged a liquid, which at the same time serves as an anchoring egg exe nt · for the blocks. This circulation line is provided with outlet openings 4- ^, through which the liquid exits and thus with the inner surface of the tube 38 ■

009815 / U4 0

comes into contact. These outlet openings 44 are essentially aligned with the upper parts of the tube 38, that is to say with the parts closest to the molten bath to bring about lower temperature gradients in the transverse direction of the molten bath 48. In addition, insulating sleeves 45 can be arranged displaceably on the circulation line 43, these being preferably located at the ends of the circulation line. With the aid of these sleeves of the outlet of the liquid The temperature gradient in the longitudinal direction of the annealing Ankes 45 can be limited, with which one is able to adjust the running in the transverse direction w temperature gradient "in the desired manner. Can also be very effectively controlled by namely, the temperature and / or the liquid flow in the adjacent rows of blocks extending circulation pipes 43 is controlled, the length of the annealing Ankes whereby comparable ^N can be shortened.

The rows of blocks and their anchoring elements can be attached to the Place where the glow tank is to be assembled. In this case the. provided with the cavities fire resistant blocks 33 in. parallel legs on the with Sealing and binding material 32 covered bottom wall 31 covered " lays. The side walls 35 »36 with corresponding openings 39, 40 are then set against the forehead blocks, likewise the sealing and binding material 37 is provided in between will. The ear 38 serving as an anchoring element is then inserted through the opening 39 in the side wall 35 a-r and through the cavity 34 of the aligned Blocks pushed through so that it can pass through the opening 40 in the other side wall 36 of the annealing tank emerges. The fasteners 41 and 42 are then mounted on the protruding parts of the tube 38. The circulation lines

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and the insulating sleeves 45 can then be easily "put on" Fohre 38 can be postponed. Be final the fire-resistant blocks 46, 4-7 placed on the end blocks, thus completing the bottom and side walls of the annealing tank.

Deviating from the above illustration, the annealing furnace also assembled from the individual parts in a workshop and then transported to the installation site. E.g. the blocks can be laid out in a row and then the tubes 38 are pushed through the cavities in the blocks. It is also possible to act as anchoring elements to screw the pipes into the blocks. In another possible embodiment of the invention a single refractory block is formed on the tube 38. Such a constructive solution is with small Tanks particularly advantageous. Such an annealing furnace installed in the workshop can then be transported to the site, where it is to be set up, stored, with the parts used for anchoring then in the previously described Way to be assembled.

In Fig. 4 a partial section of the bottom of an annealing tank is also shown, in which the embodiment according to Fig. 3 corresponding parts with the same reference numerals are provided. These are the metal wall 31 »the sealing and Binding material 32 »the fire-resistant blocks 33» of the Cavity 34 in the blocks, the side walls 35 »the sealing and Binding material 37 on the side walls 35 "as an anchoring egg ement serving pipe 38, the fire-resistant block 46 arranged on the end block of the structure and the weld pool 48 and the ribbon of glass 49.

As can be seen from FIG. 4, the side wall 35 is not in one piece formed with the metal wall 31 serving as the bottom.

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The one due to the thermal expansion of the fire-resistant blocks pressure exerted on the side wall 35 is absorbed by a compensation device 55 shown schematically, which can for example consist of a resilient element in the form of a spring or a resilient washer. Between the Side wall 35 and the iCompensator 55 is one Washer 56 arranged. The .Tube 38 serves as an anchoring element and is held in an add-on element 57, which is shown schematically in one piece with the metal base 31 is formed.

In the embodiment according to FIG. 4, this includes for the Control of the thermal conditions of the melt 48 provided System lines 58 which run through pipes 38 and through which water is circulated. Over the lines sleeves 59 can be pushed, which offer the possibility of set the transverse temperature gradient of the melt pool. These sleeves are made of one - heat insulating Material produced and thus affect the heat transfer between the water in the circulation lines 58 and the weld pool made of tin, for example.

In Fig. 5 is a. A detail is shown showing an anchoring element for the tank arrangement on the metal floor 31. This anchoring element can advantageously be provided at various points on the annealing tank and is located, for example, in its central area. The illustration shows' - '■ - = two fire-resistant blocks 33' arranged next to one another and lying on a sealing and binding material 32, over which a molten bath 48, a glass ribbon 49 runs, and the pipe 38 running through the cavity 34 of the blocks are anchored. For a better illustration, the individual distances to one another are shown disproportionately large.

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The cavity 34 and the tube 38 are circular. The anchoring element arranged between the two blocks lying next to one another comprises a tube 38 surrounding the tube Cuff 61 which is fastened on a shaft 62. This shaft 62 is provided with a threaded portion 63, which runs through a slot 64 in the metal base 31 and on this is held with the aid of a nut 65 resting against a washer 66. There is a shift through the slot 64 the arrangement in the vertical direction, i.e. in the longitudinal direction of the annealing tank is possible. The neighboring end faces of the two fire-resistant blocks 33 are with a Recess 67 is provided, thereby changing the shape of the anchoring element be adjusted.

In Fig. 6 an outer anchoring of the tube 38 according to FIG. 5 corresponding further execution s form of the anchoring on the metal base 31 is shown. In this illustration, the sealing and binding material 32, two adjacent fire-resistant blocks 33, the molten bath <+ S, the glass ribbon 49, the cavity 3 ^a in the blocks and the tube 38 serving as an anchoring element can be seen. In this embodiment, the anchoring element is located between two adjacent blocks and comprises a lug 70 welded at the point 71 on the lower side of the pipe JS . The lug 70 is provided with a shoe 72, which is suitable with the help of two; shaped angle iron-73 is held, which are welded to the metal base. This anchoring system with the extension ⁿ 0 and the shoe 72 also enables free mobility in a direction perpendicular thereto.

7 to 12 are various possible cross-sections for the cavity 34 in the fire resistant blocks 33 and for the anchoring elements. In the embodiment according to Fig. 4- both the cross-section of the cavity as well as that of the anchoring tube circular, with between

009815/1440

BATH ORIGINAL

A free cavity remains in the two circular areas. In the in jig. 8 are the corresponding embodiments Square cross-sections, the tube 38 in turn being guided in the cavity 34 with a free space between them. In the embodiment according to FIG. 9, the block is provided with an angled channel. In this embodiment, the tube 38 in each fire resistant block by a vertical shift in the direction of the arrow X and a subsequent horizontal shift in the direction of the arrow Y is used will. This embodiment is particularly advantageous when at . subsequent to the completed construction of a floating annealing tank lent individual blocks to be exchanged without fc the anchoring tube is removed. In the embodiment 10, the fire-resistant block is provided with three cavities 82, 83 and 84, the cross-section being smaller is than the cavity in the blocks previously described. No anchoring elements are inserted through the cavities 83 and 84, rather, they only serve to transport the cooling medium, e.g. in 5 "orm of air circulating in it, The Cavity 82 is used to accommodate an anchoring tube 3 & · In this embodiment, the upper part of the block influenced more favorably.

In the embodiment according to FIG. 11 in the cavity of the block is inserted from a rectangular cross-section schrägkreuzför- ψ miger iron rod 80. This creates four lines 81 through which the hedium can circulate to influence the temperature conditions. .

In the embodiment shown in Fig. 12 is in the square cross-section of the cavity of a U-shaped iron fcab 80 arranged, together with a wall of the cavity the line for the medium to control the temperature conditions forms. .

Claims

0098 15 /

Claims (1)

ir Patent claims Annealing furnace with at least one wall made of refractory blocks, characterized in that at least a wall of the annealing furnace is formed at least in part from a refractory block, the one Has a passage for a flow medium, and that the passage is penetrated by at least one element, with which the block is anchored in a bracket. 2. Annealing furnace according to claim 1, characterized in that that at least one wall of the annealing furnace at least is partly formed from a large number of assembled and fire-resistant blocks that provide a passage for have a flow medium, and that the passage is penetrated by at least one element with which the Blocks are anchored in the bracket. 3 »Annealing furnace according to claim 1 or 2, characterized in that the anchoring element consists of a Pipe is made. 4. Annealing furnace according to one of claims 1 or 2, characterized characterized in that the anchoring element consists of an angle iron » 009815 / U40 5. Annealing furnace according to one of claims 1 to 4-, characterized g e k e η η show that at least one of the fire-resistant blocks molded onto the anchoring element is. 6. Annealing furnace according to one of claims 1 to 5, characterized characterized in that the anchoring element at least one of the blocks with a free distance from it-interspersed. 7. Annealing furnace according to one or more of claims 1 to 6, characterized in that the passage w and the anchoring element have a polygonal cross-section, • and have such dimensions that rotation of the refractory blocks on it is prevented or restricted. 8. Annealing furnace according to one or more of claims 1 to 7 » characterized in that at least one of the fire-resistant blocks with a passage open to one side with an angled cross-section is provided, wherein the inner leg is penetrated by the anchoring element in such a way that 'the Block by successive shifts in different ^ can be removed in different directions. 9. Annealing furnace according to one or more of claims 1 to 8, characterized ge kenn ζ ei chn et that a plurality of fire-resistant blocks are penetrated by the anchoring element, and that at least one connecting piece between two adjacent blocks assembled in this way runs and the anchoring element connects to the bracket. 009 815 / U4 0 10. Annealing furnace according to one of claims 1 to 9, characterized marked that at least one of the Passages with devices for controlling the thermal Relationship is connected. " 11. Annealing furnace according to claim 10, characterized in that at least one of the passages with devices for differential control of the thermal conditions is connected. 12. Annealing furnace according to claim 11, characterized in that geke η η - ζ e i c h η et that at least in one of the passages heat-insulating facilities are in place. 13. Annealing furnace according to claim 10 or 11, characterized in that at least one of the passages is connected to devices for electrical resistance heating. 14. Annealing furnace according to one or more of claims 1 to 13, characterized in that the anchoring elements are tubular, and that through the anchoring element to control the thermal Conditions a medium circulates. Ip. Annealing furnace according to one or more of Claims 1 to 13, characterized in that the anchoring element is tubular and one over the entire length or part of a block or the block arrangement supplies running line, and that facilities ^ are available to pass through the line to circulate a medium to control the thermal conditions. 16. Annealing furnace according to claim 15, characterized in that the line with outlet openings 009 815 / U40 for the carculation medium in different places provided within the block or the block arrangement is. 1? .. Annealing furnace according to claim 16, characterized geke η η - . - ζ calibrate η et that the block or the block arrangement forms part of the bottom of the annealing furnace and runs transversely through it, and that a plurality of outlet openings are arranged in such a way that the distance between successive outlet openings from the end face of the block or the block arrangement to the Decreases towards the center. 18. Annealing furnace according to one of claims 16 or 17, characterized ■ g e k. e η η ζ e i c h n. et that over the line a The element covering the outlet openings is arranged displaceably on the line in order to achieve this Control circulation medium from the line. 19 annealing furnace according to one or more of claims 1 to 18, characterized in that at least one block in the annealing furnace is covered with a component, its thermal conductivity and / or density is greater is than that of the fire-resistant block. "2.0. Annealing furnace according to claim 19, characterized geke η η ζ eic et hn in that the component is made of tungsten. 21. Annealing furnace according to one or more of claims 1 to 20 ^ thereby. g e k e η η .z e i c h η e t that at least-. two of the fire-resistant. standing blocks or, the Bloqkan order next to each other and / or are arranged one above the other. ,, 00981 1950008 22. Annealing furnace according to one or more of claims 1 to 21, characterized in that the from Anchoring elements interspersed with blocks or block arrangements are aligned, with each other connect the anchoring elements to one another. 23. Annealing furnace according to one or more of claims 1 Ms 22, characterized in that at least a block or a block arrangement at least a part of the bottom of the annealing furnace "forms in which a molten medium with a greater density than the block or the blocks are "located. 24. Annealing furnace according to claim 23, characterized in that the annealing furnace with the molten Medium for the production of flat glass in the floating annealing process serves. 25. Process for controlling the thermal behavior of the inner surface of at least part of an annealing furnace wall, thereby geke η η ζ e i c hn.et that through one passage or a plurality of passages a medium is passed, the temperature of which is essentially that of the adjoining interface of the passage or the passages is different, so as to define a thermal behavior that is essentially is unequal over the length of the passage or passages. 26. The method as claimed in claim 25, characterized in that, in the central area of the annealing furnace , substantially greater heat is transferred than in the edge areas. 009815/1440 1350008 27. Process for the production of flat glass, the glass guided through a floating annealing furnace and on a river sigen material is cooled by floating, thereby marking i c h η e t that the temperatures of at least part of the floating annealing furnace can be controlled by a medium containing the refractory blocks or the fire-resistant block arrangement penetrates in at least one passage. . '■ 00981S /