DE10140007C2 - Cooling furnace for tempering large glass parts - Google Patents

Description

The invention relates to the field of the manufacture of glass parts, especially of large glass parts. Here come in particular Glass cylinder into consideration. These can have a diameter of for example 500 mm and have a similar length.

Parts of the type mentioned must be in the course of their manufacturing process from relatively high temperatures to relatively low temperatures be cooled down. This cooling process must be controlled To be done in a manner completely at the end of the process to produce stress-free vitreous bodies. This process takes place in the called cooling belt furnace instead.

Such a cooling furnace has a conveyor. Acting it is a belt conveyor with an endless conveyor belt around Rolling around and forms an upper horizontal run as well as a lower run. The upper run serves to promote the Glass objects. It is generally of a chain construction built up.

The conveyor is surrounded by a housing. The housing has such a clear cross-section that the largest parts to be treated can walk through. The housing also contains fans and Burner. The fans generate air currents that are generated by the Burners are heated and fed to the glass parts to temper them. Both the fans and the burners are located above the treatment room and thus above the glass parts. The air streams come vertically from the glass parts.  

US 2,330,984 describes a cooling furnace for glass. This has a conveyor belt that goes through the furnace, a tunnel-shaped furnace housing that Conveyor belt encloses a fan that is below the conveyor belt is arranged and the cooling air leads to the glass parts, a heating device for Temperature control of the air as well as an air delivery channel that is connected to the outlet of the Fan is arranged and which opens above the conveyor belt.

Similar cooling furnaces are known from BE-PS 557592, DE 197 21 334 C2, FR-PS 1314635, EP 0152163 A2.  

The central issue regarding the work of a refrigerator is that controlled and at the same time homogeneous cooling of the treated Glass objects, with the aim of a complete absence of tension in the material to achieve these items. However, this goal is known with Stoves are not always achieved satisfactorily. The one in the material contained voltages are not always in the necessary manner degraded so that it becomes a subsequent treatment steps Break can come.

The invention has for its object a cooling furnace described type in such a way that controlled tempering with extensive or complete reduction of internal tensions treating objects takes place.

This object is achieved through the features of the independent claims solved.

The inventor recognized the following:
In the cooling ovens used since then, the fans and usually also the burners were located above the treatment room and thus above the glass objects to be treated. In the cooling furnaces that have been used since then, the air was introduced under the chain conveyor belts, pushed through these conveyor belts so that they brushed against the outer walls of the objects on the conveyor belts, and finally extracted by means of fans. The fans were in a central position. The air flow concentrated there and the parts of the objects to be treated which were out of the central position were not detected as necessary.

There is also something else: The conveyor belts mentioned serve usually at the same time the removal of fragments that are on the Collect soil below the conveyor belts. Practice the conveyor belts thereby a clearing effect. There is therefore no room left for Arranging nozzles by means of which the air flow in a more uniform Distribution could be initiated.

The result of this is that in the previously known cooling furnaces uniform speed and a uniform flow to the individual cross-sectional areas is not guaranteed.

The basic idea of the invention is to pull the suction below the conveyor belt to attach, and the air flow from the fan to convey the upper area. The air flow then sweeps around the treating vitreous body and inevitably comes back to Intake nozzle of the fan. This leads to considerable homogenization of the air flow. Any heat flags, that is areas different heat contents within the air flow avoided or on the way from the one below Fan balanced to the mouth at the top. All in all air speed can be relatively high by applying the invention be, which leads to higher heat transfers. By the uniformity of the Cooling of the entire surface of the objects to be treated can be a significantly higher product quality or achieve a lower reject rate.

Instead of the burners mentioned, electrical heating devices can also be used be used.

The invention is explained in more detail with reference to the drawing. In it is in each shown the following:  

Fig. 1 shows a cooling oven according to a first embodiment in an axially perpendicular cross section.

Fig. 2 shows a cooling furnace of a second embodiment, in the axial cross section.

Fig. 3 shows a cooling furnace according to a third embodiment, again in the axial cross section.

The furnace shown in FIG. 1 has a conveyor device, comprising a conveyor belt 1 . The conveyor belt is endless and forms a loop, so that an upper and a lower horizontal run 1.1 and 1.2 are formed. On the conveyor belt 1 there is a support means 2, and on the carrying means 2 is located in to be tempered glass body 3 - in this case a cylinder with circular cross section. The cylinder is relatively large. It has a diameter of 600 mm and a length of 500 mm.

The furnace has an inner housing 4 and an outer housing 5 . The inner housing consists of a sheet metal wall. Together with the outer housing 5, it forms a flow channel 6 . The inner housing has an upper wall 4.1 . This forms an inlet grille consisting of a plurality of guide vanes 4.1.1 .

An essential component is a fan 7 , which is driven by an electric motor 8 . As can be seen, the fan 7 is located below the conveyor belt 1 and has a horizontal axis of rotation.

Fan 7 is a radial fan with a suction nozzle 7.1 . Through this suction nozzle, it sucks in air which it feeds into the flow channel 6 . See the arrows that illustrate the direction of flow. The air flow then reaches the area above the glass body 3 and enters the interior between the guide vanes 4.1.1 of the top wall 4 . Now he strokes along the outer walls of the glass body 3 , practically coming into contact with the entire peripheral surface of the glass body 3 . It then passes through the conveyor belt 1 formed from meshes or chains, first through its upper run 1.1 and then through its lower run 1.2 in order to finally get back to the suction nozzle 7.1 of the fan 7 .

A burner pipe lance 9 with a control device 9.1 can be seen . The burner tube lance 9 is arranged in such a way that its nozzle 9.2 is directed against the suction nozzle 7.1 of the fan 7 . In the present case, the burner tube lance 9 and the fan 7 are arranged coaxially.

The fan is equipped with a speed control so that the Heat transfer is precisely adjustable.

In the embodiment according to FIG. 2, the burner tube lance 9 is located in the upper region of the flow channel 6 . The lance is again arranged horizontally. Your mouth 9.1 runs parallel to the air flow.

In the embodiment according to FIG. 3, a fresh air inlet 6.1 to the flow channel and a hot air outlet 6.2 from the flow channel 6 can be seen .

The cooling furnace can be constructed as follows:
In the conveying direction of the material to be treated - in the present case the glass cylinder 3 - fans 7 can be arranged alternately on one side and on the other side of the flow channel 6 .

Due to the symmetrical arrangement, the number of Fans and the burner can be varied between one and two. In For example, zones with higher heat outputs could have two fans are used, which are opposite in the conveying direction are arranged as mentioned. The consequence of this is that each Burner tube the flame is oriented towards the fan inlet. In Zones with lower heat transfers are usually sufficient Fan that supplies the entire system in the zone in question.

In zones with higher cooling capacity, two fans can be used be arranged opposite one another, the cooling capacity being determined by a corresponding cooling flap control can be regulated.

The arrangement of the gas burners - as shown here in the top horizontal flow channel section, or at the level of Fan axis - become disruptive radiation influences of the burner tube significantly reduced.

Claims (3)

1. Cooling furnace for controlled tempering of glass parts ( 3 ) by means of cooling air;

• 1. 1.1 with a conveyor, which comprises a conveyor belt ( 1 );
• 2. 1.2 with a housing ( 4 , 5 ) which encloses the conveyor;
• 3. 1.3 with a fan for supplying air to the glass parts;
• 4. 1.4 with a heating device ( 9 ) for tempering the air;
• 5. 1.5 the fan ( 7 ) is arranged under the conveyor; characterized by the following features:
• 6. 1.6 there is an air delivery channel ( 6 ) which is connected to the outlet port of the fan ( 7 ) and which opens above the glass part to be treated ( 3 );
• 7. 1.7 of the mouth of the air delivery channel ( 6 ) is followed by a guide vane grille ( 4.1.1 ) for deflecting and directing the air flow against the glass part ( 3 );
• 8. 1.8 the fan ( 7 ) is - seen in a vertical cross section perpendicular to the conveyor axis - next to the conveyor belt ( 1 );
• 9. 1.9 the fan ( 7 ) is arranged such that its axis of rotation is horizontal;
• 10. 1.10 the heating device comprises a burner tube lance ( 9 );
• 11. 1.11 the outlet nozzle ( 9.2 ) of the burner tube lance ( 9 ) is arranged in the air flow;
• 12. 1.12 burner tube lance ( 9 ) is arranged such that its outlet nozzle ( 9.2 ) runs parallel to the air flow.

2. Cooling furnace according to claim 1, characterized in that the burner tube lance ( 9 ) between the conveyor and intake ( 7.1 ) of the fan ( 7 ) is arranged. 3. Cooling furnace according to one of claims 1 or 2, characterized in that the burner tube lance 9 is arranged between the fan ( 7 ) and the guide vane grids ( 4.1.1 ).