FI120972B - Convection heater for heating a glass slab - Google Patents

Description

MY CONVENTION HEATING TO HEAT GLASS PLATE

The invention relates to a convection heating furnace for heating a sheet of glass, the furnace being provided along a conveying path, such as by rotating rolls and the furnace further comprising heating elements for heating air blown against the glass sheet; a portion of the heating elements for heating the blowing air are arranged and each duct comprises air blowing means on its side facing the glass plate.

Convection heating ovens according to the preceding preamble, e.g. EPO 0910553 B1 and FI Application Publication 20030482. In these furnaces, air blowing cannot be uniformly distributed across the glass surface in the transverse direction of the glass propagation direction. This is due to the fact that the blowing cannot be effectively conducted to the glass surface in the area between the blowing ducts, since at the bottom of the ducts, the extreme jets of air should be directed obliquely to the glass so that the jets hit the glass surface. The showers are easy to tilt, but it follows that the showers do not reach the surface of the glass because they are affected by a strong side air return, which tends to swing up through the extreme jets into the space between the air ducts. The outermost showers thus reach very poorly into the glass and the temperature of the glass at this point is lower than in other places. Glass oscillation does not mate the situation in this direction.

As a result of the above, when the glass is heated in bands between the air passages in strips about 20 to 40 mm wide from the end of the glass, these strips become visible bands after heat treatment such as hardening under certain conditions. The quality of the glass suffers here and the glass may no longer be fit for purpose.

To overcome the above disadvantage, a new convection heating furnace has been developed in which the glass-warming air blast is characterized in that the air blowing members are 2 to the air, with said housing disposed transversely or at an angle (X relative to the duct).

An advantage of the convection heating furnace according to the invention is that all the blowing nozzles can be directed perpendicularly towards the glass. There is no point in the inferior blasting of the glass surface, since the nozzle groups can be arranged in an almost continuous queue in the transverse direction against the direction of glass travel. When the nozzle assembly is wider than its blowing duct acting as its mounting body, adjacent nozzle assemblies can be positioned even slightly overlapping to achieve a complete nozzle array formation in the transverse direction of the glass. The nozzle arrays can also be interleaved so that they are rotated at a slight angle from a direction completely transverse to the ducts. When all the nozzles are perpendicular to the glass, the nozzles can be lowered closer to the glass surface, with constant distribution of the blowing and high heating efficiency of the air jets.

The invention will now be explained in more detail with reference to the accompanying drawing, in which Figure 1 shows nozzle groups according to the invention as seen in the direction of travel of the glass.

Figure 2 shows the nozzle groups as seen in the direction of the support rollers.

Figure 3 shows a sectional view of the nozzle assembly in the direction A-A.

Fig. 4 is an oblique view of the housing according to the invention.

Figure 5 shows a housing A-A in section.

Figure 6 shows the nozzle housings on the surface of the channels as seen from the direction of the glass.

Fig. 1 shows a section of the convection heating furnace in which the glass 3 is supported and rolled by rollers 4. Only the heating rigidity above the glass 3 is shown, but naturally the same arrangement can be arranged underneath the glass. The heating air flow, along the ducts 1 in the direction of travel of the glass 3, is heated by the heating element 12 and flows downwardly from the duct to each group of nozzles. Each nozzle assembly is formed as a housing 2. Such a housing is made, for example, by compressing a sheet of sheet such that two such shaped sheets, when assembled, form directed discharge nozzles 6 as shown in Fig. 3 as seen from the direction of the glass sheet. For example, the form plates can be connected by spot welding to surfaces where the plates lean against each other, such as surfaces 11 and edges 7. The housings 2 can be made wider than the channel 1, 0. The enclosures are then in a single queue. The housings 2 may be slightly interlaced, not prevented by the construction. However, with this solution of the invention and its various variations, the jet point 10 between the blowing jets on the surface of the glass sheet 3 is always completely removed. The space 5 between the channels 1 shown in Figure 1 is quite sufficient for the return air if it is e.g. 15-20 mm. The housing 2 can be easily made e.g. 20 mm to 50 mm wider than the channel 1, whereby a homogeneous transverse jet sequence is always available in which the jet spacing and jet intensities are maintained regardless of the housing distribution.

Figure 2 shows the boxes 2 on the side. There is ample room for return air between successive housings 2, indicated as compartments 5.1. From these, the return air rises without disturbing the other showers. After state 5.1 the return air rises to state 5 between channels 1.

Fig. 3 shows the housing 2 as seen from the direction of the glass 3. The discharge openings 6 can be pressed almost round, but the most suitable shape may be a slightly flattened circle. The housing has folds 8 at its edge, from which the housing can be spot welded to channel 1, for example.

Fig. 4 is an oblique view of the housing 2 with discharge openings 6. The housing is wider than the channel 1, as is the case with the housing of Figure 1.

Fig. 5 is a sectional view showing a nozzle housing 2 'having a single narrow slot for a discharge port 6. Such a housing is slightly easier to manufacture than the housings of Figs. 1-4. In Fig. 6, the housings of Fig. 5 are mounted slightly transverse to the surface of the channel 1. Angle (X is, for example, 10 - 20 °).

Claims (5)

1. Convection heating furnace for heating a glass sheet, into which oven the glass sheet (3) comes along a conveying path, likewise on rotating rollers (3) and to the furnace further includes the heating elements (12) for heating the air blown against the glass sheet, a fan and ductwork for blowing said lute to the glass sheet and ducting for the air blowing comprises longitudinal channels (1) in the direction of movement of the glass sheet (3) into which channels at least part of the blowing air heating elements (12) are adapted and each channel (1) comprises in its side directed towards the glass plate (3) air blowing means, characterized in that, as the air blowing means, there are nozzle groups of the firm which are firmly in the side of the channel (1), in which nozzle group is formed by means of two thin plates which are molded, said plaques are generally in one another for forming a housing (2), said housing comprising one or more directional exhaust ducts (6) for blowing air and wherein said housing (2) is positioned transversely or at an angle CL which deviates from the transverse winkein with respect to the duct (1) Convection heater according to claim 1, characterized in that the drain duct or ducts (6) are directed perpendicular to the glass plate (3). Convection heating furnace according to claim 1, characterized in that the space (5.1) between the successive housing (2) is arranged as passage for return air in the first stage of return and after the return air is arranged to flow between the adjacent ducts down (5). Convection heater according to claim 1, characterized in that the width of the nozzle group belonging to the housing (2) is greater than the width of the side of the air duct (1) on which the housing is attached. 5. Convection heater according to claim 1, characterized in that the halves of the housing (2) are connected to each other by spot welding.