DE105148C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 24: Combustion systems.

PAUL FREYGANG in DRESDEN-FLAUEN. Gas generators.

Patented in the German Empire on March 9, 1898.

In the case of gas generators, especially those which use very highly heated gases - e.g. B. Air, steam, furnace exhaust gases, used individually or in combination - operated, it seems advisable for various reasons to support the fuel - Rust, sliding vaults, plates and so on - the direct effect of high temperatures not to be suspected, as this support wears out more or less quickly, the operation of the ash fall is made much more difficult and with those in the glowing state extracted ash masses, slag and fuel waste a not inconsiderable Heat loss would occur.

In the gas generators shown in FIGS therefore the hot operating gases - air, steam, furnace exhaust gases and so on - not introduced into it through the support of the fuel, and likewise For the same reasons, there is little in the way of deriving the evolved combustion gases from the ash fall off instead. In the case of a supply and discharge of particularly highly heated gases in the upper part of a gas generator would in turn be the filling devices arranged on the same suffer a lot and soon become unusable.

For these reasons, a new arrangement of the canal openings for supply and discharge is required of the gases, in such a way that the fuel support as well as the Filling devices are protected from damage by heat. At the same time here is this Openings for inlet and outlet of the gases and the connecting channels one layer and shaping has been given, whereby it becomes possible to have their mutual effect to be exchanged, as is necessary e.g. for stoves with changing flame directions appears as soon as such in direct connection with the associated gas generators stand. Since the supply and discharge of gases in each of the channels takes place continuously but alternately, it appears here It is advantageous that the gas generators without any shut-off devices, as otherwise become necessary to bring in connection with the furnaces.

In Fig. 1 and 2, two gas generators built in accordance with the above-mentioned points of view are shown in the simplest form. The operating gas is fed into one of the two channels c and C ₁ , which open laterally between the ash trap and the filling device, and the developed fuel gas is discharged in the other of these channels, whereby the freshly poured fuel stored _{over the channels 0 and O 1 is} the same as at f by simple locking plates indicated filling devices protects against the action of the hot gases. While Fig. Ι shows the channels c and C ₁ arranged one above the other, they are indicated in Fig. 2 opposite. As in the other figures, the arrows indicated here indicate the directions in which the gases can flow through the fuel.

In Fig. 3, the channels c and C ₁ at ο and O ₁ also open opposite one another into the gas generator, only here the openings are through built-in transverse

(2nd edition, issued on January 16, igoo.J

walls facing downwards to move the strikethrough gases deeper into the gas generator to penetrate.

4 and 5 show, in two vertical sections, a gas generator in which the mutually opposite channels c and C ₁ also have such transverse walls at 0 and O ₁ , which, however, are of the same height here, while in FIG. 3 they are different heights . Furthermore, here the shaft is designed in two spaces by a partition s in its upper part and at f and f _i carries the filling devices which supply the fuel to the casting halves, which, as in the other figures, are indicated by simple end plates.

6, 7 and 8, a gas generator is shown in two vertical sections and a horizontal section, in which the channels c and C ₁ and their mouths 0 and O ₁ for supply and discharge of the gases are next to each other, these gases be forced by the partition s dividing the shaft above and its special shape to go through it in its entire width, as the drawn arrows indicate.

FIG. G, 10, 11 and 12 illustrate some further possible different cross-sectional shapes and arrangements of gas generator shafts, namely, Fig. 9 such and to anschliefsenden of triangular Grundrifs represents with a septum 's at an angle at 0 and O ₁ Channels c and C ₁ . 10 and 11 show gas generator shafts of square cross-section with the channel openings O O ₁ and O ₂ , the gas generator according to FIG. 10 having a partition s and that according to FIG. 11 having two partition walls s and S ₁ .

12 shows a round gas generator shaft provided with a partition s , into which four channels _{open at 0 O 1} O ₂ and O ₄ , two of which are used for supply and two for discharge of the gases. ■ With this gas generator in particular, the partition s can be omitted if the designs are small.

Corresponding to the permeating gases due to the tightness and expansion of the Fuel layer opposing resistances, the voltages prevailing in the channels the gases and the respective operating conditions, it will have to be set up in which How and by what means the operating gases supplied and the gases to be discharged Combustion gases are moved through the fuel layer and whether in the ash fall · to constant or temporary support of the reactions going on in the gas generator Under wind - dry or wet - is introduced or not.

Claims (1)

Patent claim: Gas generator, characterized in that the side between the grate and the filling device Channels are attached, of which any one or more of the Process gases introduced and left over by the other or the other remaining the fuel gases produced are discharged, and at such a height that with the reversible flow direction of the gases neither the filling device nor the grate of the main flame. 1 sheet of drawings.