DE3647C - Glass melting furnace with regenerative gas firing - Google Patents

Description

1878.

Class 32.

ERNST HERMANN SIEBERT in BERLIN. Glass melting furnace with regenerative gas firing.

Patented in the German Empire on May 7, 1878. Longest duration: February 2, 1891.

In the accompanying drawings the glass melting furnace is shown in two horizontal and two vertical lines Shown in sections, in which like letters indicate like parts of the furnace.

In FIGS. 1 and 2, α is the gas supply duct through which the gas passes to the gas exchange valve B '; by setting the flap h , the gas can be directed to b as well as to b ' .

In Fig. 2 the flap h is set so that the gas gets into the channel b , from there into the regenerator system C, passes through this and passes through opening d into the combustion channel £>'.

The air necessary for burning the gas enters the shuttle valve B " at ο , through which it can be directed to c as well as to c ' .

In Fig. 2, the shuttle valve B "is set so that the incoming air reaches the duct system c 'c' , from this into the regenerator system C" and from there through opening d ' into the combustion duct D', here the air also meets the gases coming from d come together and combustion occurs.

The flame generated here takes the direction of the upper furnace to be heated, generates the required temperature here and runs the same through combustion channel D "; from the same the outgoing fire can be directed to the regenerator system F ' as well as to F" , depending on the gas or air ■ should be specially preheated.

As the drawing shows, part of the outgoing fire air goes to F ', the other to F ", passes through these regenerator systems and deposits its heat in them and, cooled down, passes to the changeover valves B' and B", and from here through the channels / and / 'and through the chimney slide 1 and 2 after the chimney; by turning the reversible flaps h , the direction of both the gas and the air flow is changed, the gas now passes through duct b ', regenerator system F' and duct e into combustion duct Z>"; the air through duct system cc, regenerator system F" and channel e 'in the combustion channel D ", the combustion is done now in the combustion channel D'', the flame runs through the oven in the opposite direction and the same verläfst by combustion channel £>'.

The rotation of the shuttle valves takes place in certain periods of time, with the flame appears now on the right, now on the left in the upper furnace; be due to repeated decline of the fire the regenerator systems are heated more and more, which in turn increases the temperature in the Oberofen is increased and that up to the highest heat levels.

This furnace system is known and has been tried and tested by me in around 80 plants and has been improved in many ways.

Despite all the improvements and efforts, it has not yet been possible to this system thoroughly and generally for those purposes which lead to its creation require high temperatures to apply.

The main fault of this system lies in the alternating flame, which is now on the right, now appears on the left in the upper oven and thereby generates uneven heat in the oven itself, because where the flame enters there is always a higher temperature than where it is Oven runs out; in this way the parts which first suffer from the entering flame are overheated and run ahead in their processes, while those farther away from the flame Parts remain behind.

The larger the furnace, the greater this temperature difference. The same is special very inconvenient in the glass melting furnaces where harbors are used.

In order to compensate for this error as much as possible and for the one further away from the flame To give parts of the furnace the necessary temperature, the temperature is raised higher than is necessary for the process; this resource but not only uses more fuel,

but, what is far more dangerous, durability of the furnace is thereby called into question.

This aid, to compensate for the samples by increasing the temperature, is also successful only as soon as the furnace is closed, as is the case with the melting process of glass, When working on the glass, on the other hand, the furnace is open, the thermal tension has ceased, the flame shows the effort to reach the drainage duct only to a small extent.

Where the flame enters the furnace there is an overflow of heat, while on the other End, where the flame leaves the furnace, only insufficiently due to lack of heat Elaboration of the glass can be done.

The remedy against these evils is the same as in the melting process; one increases the intensity and effect of the entering flame by letting more gas enter, and the draft of the furnace increased, but this caused a significant loss of fuel will.

The aim of the invention is now to eliminate these errors.

In order to achieve this, the openings kk are attached in the surrounding walls, the so-called rings, between each two ports in the upper furnace, where the ports are located, Fig. 1 and 4. These openings open into the horizontal collecting channels mm, Fig. 1. These are in connection with the vertical channels a "b", Fig. 2, which go under the furnace base and where the channels // 'open.

As can be seen in the accompanying drawings, these ducts // 'go up to the air supply ducts cc', Fig. 3, and run underneath them, separated from them by clay plates, along their entire length to / ". Here both ducts unite to a duct x, which leads the outgoing fire air through the chimney slide 3 to the chimney, FIG. 2.

The effect of this device is now as follows.

During the melting process in glass production,. so when the highest temperatures are required, the stove works with an alternating flame. As soon as it becomes necessary to raise the temperature of parts of the stove, the chimney slide 3 is pulled. Hereby part of the flame is compelled to take its way out through the openings kk , whereby heat is supplied to the ports on the side remote from the direction of the flame.

By closing and opening the small outlet openings kk, which can be done by placing small stones in it, one has the power to determine the amount of heat which is to be drawn into a certain part of the furnace.

This amount results from practice.

The heat that leaves the furnace through the openings kk is not lost, since the exhaust ducts up to the air supply ducts are inside the furnace, and the heat deposited in these ducts benefits the total furnace heat by transmission.

The remainder of the heat is given off by the outgoing fire air to the feed air on the way to the chimney, in that the exhaust ducts // ', which lead the fire drawn through the openings kk to the chimney, run along their entire length under the air supply ducts cc', and from these are only separated by clay plates, which absorb the heat and give it off to the feed air.

When working out the glass it is important that the glass is not in the ports too cold and not too hot, and in the furnace itself there is a uniform warmth.

This condition applies when only one flame is used, and always on one End of the furnace by no means fulfilled.

The invention therefore aims to use two flames in the preparation of the glass. This is achieved by closing the chimney slides ι and 2, which stops the fire from falling through the regenerator systems; thereupon both gas exchange B ' and air exchange B "are placed in the middle, so that the flaps of the same assume the positions k'.

In this position of the valves, both the gas and the air flow are divided into two parts.

Streams of gas now pass through regenerator systems C and F ' , and through regenerator systems C " and F" streams of air, which combine in the combustion channels £>' and D " and form two flames, whereby the fire in the furnace itself is evenly distributed Position of the flaps of the shuttle valves you can either strengthen or weaken each of these two flames.

Chimney slide 3 is pulled so that the flames do not find their way out through the work holes, and here disturb the workers in their work, but are used to keep the ports and their contents at the correct temperature. In this way the outgoing fire is forced to take its way out around the harbors through the openings kk . By adding gas and air and moving the chimney slide 3, one has the power to keep the contents of the ports at the desired temperature, and only from the working holes

to let in as much flame and outgoing fire air as the worker to his work requirement.

Claims (1)

Patent Claims: i. The use of changing and constant flames in regenerative gas stoves, without the need for the fire air to flow out of the working holes. The arrangement of trains in the side walls of the melting room, which through a separate duct that does not touch the regenerators, the flue gases with suitable Position the gas and air valves and discharge the chimney slide directly into the chimney. For this purpose I sheet drawings.