DE1053146B - Electric nozzle for the production of glass wool, rock wool or the like. - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

kl. 32 a

INTERNAT. KL. C 03 b

EDITORIAL 1053146 "^

V8495IVc / 32a

REGISTRATION DATE: FEBRUARY 16, 1955 NOTICE I »U O

DE-REGISTRATION 7 7 r \ C

AND ISSUE OF THE ό / "0 O
EDITORIAL: 1 9 MARCH 1 9 S 9

One knows flow nozzles for the production of glass wool. Rock wool od. The like., Which are open in the axial direction to both sides and are fed with a gaseous medium or steam for the purpose of defibration of flowing through ^c e di nozzle melt flow. In these known contact nozzles, in which the freely flowing melt stream flow is deflected at an angle through the nozzle, the defibration takes place essentially in connection with the outlet end of this nozzle.

In the interior of the nozzle, defibration to any significant extent cannot occur because the clear free cross-section of this known nozzle is adapted approximately to the diameter of the melt flow is. This means that for the defibering process, i. H. for the formation of the fibers within the nozzle, there is insufficient space. There are also Ströni nozzles that come into consideration here Type known, which is connected downstream of the outlet opening of the melting container in the axial direction of the melt flow are. In these known arrangements, too, the outlet cross-section of the flow nozzle is approximately corresponding to the cross section of the outlet opening of the melting container. Significant amounts of air can consequently not when the melt flow flow passes through the flow nozzle are entrained, especially since the direction of the steam jets emerging from the cavity of the flow nozzle are mounted at an acute angle to the longitudinal axis of the flow nozzle that almost a restricted zone for the Passage of air through the flow nozzle must arise.

The invention consists primarily in the fact that the clear free cross-section of the nozzle around is several times larger than the cross section of the melt stream flow. This means that within the Nozzle has now created sufficient space for the individual fibers to develop in the area the nozzle, on the other hand has the larger internal cross-section of the nozzle compared to the cross-section of the Melt stream flow the particularly important sense that απ the nozzle open on both sides through the Exit of the gaseous agent or steam, air is sucked through the nozzle to a significant extent will. It is precisely this air that is sucked through the nozzle that is decisive for the air that is already in the area The fiberization process that begins at the nozzle and has a strong impact here.

According to the invention, it has been found to be particularly expedient that the clear free cross section the nozzle widens conically in the direction of the melt stream flow. This characteristic is essential because, as detailed tests have shown, this results in perfect fiber formation in the area of the Contact nozzle for the production of glass wool, rock wool or the like.

Applicant:
United cork industry

Corporation,
Mannheim, Karl-Ludwig-Str. 20-24

Nozzle is favored. As a result, the parts torn off by the melt flow have a steadily growing one Space is available, and this results in a mutual welding of the parts that have just been pulled out Thread bent forward. The air drawn into the nozzle is very quickly driven by the melt stream flow increased in temperature. The air therefore tends to expand. the The conical design of the cross-section of the nozzle should be an impermissible one caused by the air heating Avoid increasing the air pressure, as an air congestion that occurs here is harmful to the fiberizing process were.

If the outflow slot of the flow nozzle for the gaseous agent is designed in the sense of a Laval nozzle, so thereby the outflow speed is increased still significantly, so that again a means is given to achieve the desired, as fine as possible fiber or thread thickness.

Further details of the invention emerge from the exemplary embodiments shown in the drawing, namely shows

1 schematically shows a melting furnace with a forehearth and nozzle arrangement,

2 shows an annular nozzle on an enlarged scale,
3 shows a section along the line III-III,

4 shows a fan-shaped flow nozzle in section along line IV-IV of FIG. 5,

Fig. 5 is a plan view of the flow nozzle according to Fig. 4,

6 shows a circular flow nozzle in section along line VI-VI of FIG. 7,

FIG. 7 shows a plan view of the flow nozzle according to FIG. 6.

According to FIG. 1, rock is melted in the shaft furnace 1 in the usual manner. The melt passes over the channel 2 in the forehearth 3. In this forehearth 3

809 770/131

the melt 4 is at the desirable melting temperature held. The melt flow 6 then emerges from this forehearth 3 through the opening 5. before The flow nozzle 7 is now arranged on this melt flow 6. With number 16 there is an intermediary Extension tube called.

The ring nozzle 7 is provided with a hollow jacket which leaves an annular outlet slot free so that the steam introduced into this hollow jacket via the connecting piece 9 in the form of a ring in that shown in FIG. 1 Arrow direction emerges from the flow nozzle.

The inner cross-section of the flow nozzle according to all exemplary embodiments is in the direction of the melt flow extended to particularly support unimpeded fiber formation.

For the effect of this flow nozzle it is of considerable importance that the flow nozzle in the appropriate Elevation is adjusted with respect to the outlet opening 5 of the melt flow flow, namely so, that the desired angular deflection of the melt flow flow through the flow nozzle is actually achieved will. This deflection is expressed in the way that the melt flow in the height range of the The axis of the jet was almost torn off, and at this end the melt stream flow like a short one fluttering flag dissolving into individual rays affects.

In Figs. 2 and 3, the annular nozzle is shown on an enlarged scale. By comparing the two FIGS. 2 and 3, it can be seen how the melt flow 6 emerging from the opening 5 is torn off at its lower end at the level of the axis of the annular nozzle 7. This flag formation is indicated in Fig. 3 with number 9 a. In the jacket cavity 10 of the flow nozzle steam is about 5 atm., Z. B. saturated steam, let in via the nozzle 11. This steam emerges at the annular outlet slot 12 in such a way that a steam jacket 13 is formed.

The fiberization process of the melt begins with the formation of the plume 9a, it is continued in the conical cavity 14 of the flow nozzle and is finally completed in the steam jacket cavity 15. In particular when using heated air and the interposition of the extension tube 16 (Fig. 1), it is possible to produce a to achieve particularly long fiber or thread formation of the finest strength. In Fig. 1 it is also indicated in this sense that a pipe 17 is connected to the forehearth 3 through which heating gases are sucked in from the forehearth by means of the nozzle 7. In order to be able to set the correct quantity ratio between the heating gases and the fresh air, a connecting piece 18 with a throttle valve 19 is attached to the pipe 17. According to FIGS. 4 and 5, the flow nozzle has a fan shape. The nozzle consists of the central part 20a and the outer parts 20 and 21. These parts are, as shown in FIG. 5, fan-shaped. Between the parts 20 a on the one hand and the parts 20 and 21 on the other hand are the cavities 21 α and 21 b, to which the steam supply nozzles 21 c and 21 d lead. B of the cavities 21a and 21, the discharge slots 22 and 23 to close. Depending on the size of the angle, which is determined by this fan shape, a correspondingly fine fraying of the melt flow is achieved, due to the corresponding arc length of the outlet slot.

If the flow nozzle according to FIGS. 6 and 7 of the drawing is designed in the shape of a circular area, then results an exit ring surface 24, which corresponds to the circumference of the circular disk shape of the flow nozzle, so a

ίο the particularly large length of the outlet opening Jet. In this case, too, the circular flow nozzle consists of an upper part 25 and a lower part 26. Both tails are hollow for the reception of the gaseous agent, its supply via the nozzle 27 and 28 takes place. In the fan-shaped flow nozzle according to FIGS. 4 and 5, the fiberization / one 29 of the melt stream flow limited by the working zone 30, 30 a of the steam emerging from the nozzle, while in the nozzle according to FIGS. 6 and 7, the defibering zone 31 limits the flow of the melt stream is through the two opposite working zones 32 a and 33 a of the emerging from the nozzle Medium. The fibrillation plume of the melt stream flow is with the nozzle according to FIGS. 4 and 5 Numeral 34, denoted by numeral 35 in the nozzle according to FIGS. 6 and 7.

Claims (6)

Patent claims: 1. Current nozzle for the production of glass wool, rock wool or the like. That, in the axial direction open on both sides, is charged with a gaseous agent or steam for the purpose of defibering the freely flowing down, angularly deflected, flowing through the nozzle Melt flow, characterized in that the clear free cross section of the nozzle is several times is larger than the cross section of the melt stream flow. 2. Contact nozzle according to claim 1, characterized in that the clear free cross section of the The nozzle widens conically in the direction of the melt stream flow. 3. Current nozzle according to claim 1 and 2, characterized in that the nozzle is designed in a fan shape is. 4. Current nozzle according to claim 1 and 2, characterized in that the nozzle has the shape of a Has circular area. 5. flow nozzle according to claim 1 to 4, characterized in that the outflow slot for the gaseous means or steam is formed in the sense of a Laval nozzle. 6. flow nozzle according to claim 1 to 5, characterized in that on the inlet side of the nozzle this is preceded by an extension tube for the flow of melt flow. Considered publications:
German Patent Nos. 594 764, 745 021, 078, 746 378, 811 139, 862 423, 903 795;
British Patent No. 656,706. 1 sheet of drawings 809 770/131 3.59