Lars
Leksander
Slyngbom
Lars
Leksander
Slyngbom
| 1. | Boiler with suspended arch at the firing opening and constructed for the combustion of solid fuel which, when being heated and/or burned, gives off combustible gasses, c h a r a c t e r i z e d in that an essentially smoke and gastight radiation shield (3) having an essentially smoke and gastight connection with the front wall (6) and the side walls of the firing chamber (11) and placed in a line .above the suspended arch (2) , extends downwardly inclining in over the hearth (10) and covers a greater part of this than the suspended arch (2) , and in that an in¬ let (9) for secondary combustion air is disposed above the hearth (10) and under the radiation shield (3) , preferably opening out in the firing chamber (11) under the suspended arch (2) . |
| 2. | Boiler according to claim 1, c h a r a c t e r i z e d in that the length of the radiation shield is at least half of the distance from the front wall (6) to the rear wall (7) of the firing chamber (11) , and preferably at least 6/10 of this distance. |
| 3. | Boiler according to claims 1 or 2, c h a r a c ¬ t e r i z e d In that the radiation shield (3) is built up of suitablyshaped, temperature resistant elements (4) of ceramic material, and in that this nonselfsupporting radiation shield (3) is suspended in a supporting structure, for example of tubes (5) which, by having water passed through them when the boiler is in operation, are kept cooled to so low a temperature that the supporting ability of the tubes (5) Is maintained. |
| 4. | Boiler according to claim 3, c h a r a c t e r ¬ i z e d in that the suitably—shaped, ceramic elem¬ ents (4) are formed in such a way that they can dev¬ elop the desired degree of smoke and gastightness in the radiation shield (3) without mortar filling between the elements (4) or between these and the walls of the firing chamber, and that the radiation shield (3) is, moreover, formed in such a way that its effective extension In the direction towards the back wall (7) of the firing chamber (11) can be chan¬ ged,by the Insertion or the removal of some of the suitablyshaped, ceramic elements (4) . |
This invention relates to a boiler for the combustion of solid fuel which can give off inflammable gasses, and which is built with suspended arch over the fir- • ing place.
Boilers of this kind have previously been very wide¬ spread and, after the recent years' violent increases in the price of fuel oil and natural gas, have again become economically attractive, particularly for lar¬ ger heating installations. Not least, boilers for the burning of coal, which gives off inflammable gasses when heated, are of great interest, the reason being that from the point of view of price, coal is a des¬ irable fuel and is expected to remain so for a great number of years. It is known that coal-burning boil- . ers of known construction normally have efficiencies of a maximum of 78% of the theoretical heat content of the coal, depending somewhat on the kind of coal and the construction of the boiler. The reason that the efficiency is not greater is that the inflammable gasses given off by the coal to a wide extent leave unburned by way of the chimney and are lost. Only in high-pressure boilers, where the temperature of the firing chamber is very high, and where the tempera¬ ture in the boiler's burning-out opening therefore lies considerably above the ignition temperature of the gasses, can one achieve a generally complete com¬ bustion of the given off gasses with secondary air and an efficiency of around 90%. In boilers for the heating of water, no effective and cheap construction for achieving such an efficiency is known.
The object of the present invention is to provide a construction which, when used in generally known boil¬ ers for the heating of water by the burning of solid fuel which gives off inflammable gasses, especially coal, results in an effective combustion of the in¬ flammable gasses given off, thus enabling the high efficiencies desired to be achieved. In addition, the construction according to the invention can be used in connection with various firing systems, for exam- pie travelling grate and stoker firing etc.
According to the invention, the above object is ach¬ ieved with, a boiler as presented and characterized in the main claim. The advantage of disposing a down- wardly sloping, reasonably smoke-tight radiation shield in the manner described is that the combust¬ ible gasses, which are given, off mainly ' In the area covered by the radiation shield, rise up under this, are mixed with secondary air which is fed to this area, and ignited, the reason being that the space under the radiation shield has a high temperature (both a high. air. temperature as well as a high radia¬ tion temperature] before the mixture of secondary air and combustible gasses reaches forward to the rela— tively narrow burning-out opening rearmost in the boiler. Since the combustible gasses are thus ignited and completely burned in the firing chamber In the boiler, It is possible with boilers of generally known construction to achieve the same high efficiencies as those known from oil or gas-fired boilers and from coal-fired high-pressure boilers.
It is an advantage, providing that the radiation shield is built out so that it extends more than half
-way backwards towards the rear wall of the boiler, and particularly advantageous if it reaches out at least 3/5 of the distance to the rear wall of the boiler, leaving a burning-out opening of 2/5 or less of the boiler's length. The advantage is that the long extension increases the average time for which the gasses are in the area in which they can be ignited, and thus also increasing the possibility of a high efficiency in the boiler. Precisely how long the rad¬ iation shield must be depends on the construction of the boiler and the fuel being used, but the correct length can be found in a simple manner by those fam¬ iliar with the technique, for example by the taking of smoke analyses.
By suspending the radiation shield as presented and characterized in claim 3, particular advantage is achieved in that the supporting construction for the radiation shield is also a heating surface in the boiler construction, whereby the materials thus at the same time fulfil several functional purposes, which contributes towards a cheap total construction.
Finally, the invention can be characterized in the manner presented in claim 4. The advantage of the loosely disposed but secured elements is that it is not only easy to undertake replacement, when this is required after a certain period of operation, but al¬ so possible in a simple and quick manner to change the size of the radiation shield by the removal or insertion of some of the ceramic elements. The latter can be advantageous when changing between types of fuels having different gas contents and varying ig¬ nition temperatures for the gasses given off.
It should also be noted that the invention has been made in connection with the work with a new suspended arch which is described by the same inventor in a pat¬ ent application submitted together with the present description, and which can also ' be expediently formed- with the use of the non-supporting construction of shaped, ceramic elements which are suspended in a supporting structure as described above.
The invention will now be described in closer detail and with reference to the accompanying drawing which shows a vertical longitudinal section through an ad¬ vantageous embodiment of a boiler according to the invention.
The boiler is indicated in its entirety by the figure 1. The suspended arch 2 is placed at the feed opening for the solid fuel which, in this boiler, Is supplied by a travelling grate which is the bed of:.the.hearth__ 10 in the firing chamber 11. In accordance with the invention, the radiation shield 3 extends from the front wall 6 of the firing chamber from a line above the arch 2, smoke-tight and with smoke—tight connec¬ tion with said front wall 6 of the firing chamber 11 and two side walls sloping downwards in over the ... hearth 10. The radiation shield 3 is built up of suitably-shaped ceramic elements 4 which comprise a non-selfsupporting shield which is supported by a number of parallel tubes 5 sloping upwards from the back wall 7 of the firing chamber 11, where the in-: " . side of each tube 5 in the supporting structure is in open connection with the water chamber in the back wall If the boiler. Foremost in the boiler 1, the tubes 5 which support the radiation shield in a cor-
responding manner are each connected to the water chamber in the front wall of the boiler. With this construction, the boiler water - helped by the siphon effect - can flow freely in an upwardly inclined man- ner through the tubes, thus holding these tubes suf¬ ficiently cooled during the operation of the boiler, so that they do not lose their supporting ability. In the shown boiler 1,-the supporting .tubes 5 used have a circular cross-section, but other cross-sec- tions can be used, for example oval or rectangular. Each of the suitably-formed ceramic elements 4 have a breadth dimension at right angles to the longitud¬ inal section ' shown in the drawing which is equal to the distance between the tubes 5. The cross-section of the elements 4 in the direction at right angles to the tubes 5 is similar to that of an hourglass, in that in each side of each element 4 there is formed a lengthwise recess or groove of a size and shape which corresponds in the main to the half cross-sec- tion of the supporting tubes 5. The thus suitably shaped elements 4 are hung on the tubes 5 and, when the boiler is in operation and the elements are heat¬ ed, close so tightly together that the smoke dis-: charge is forced essentially backwards in the boiler. An inlet 9 for secondary air is provided through the front wall 6 of the firing chamber 11 under " the arch 2.
In the main, the boiler 1 functions like known boil- ers for solid fuel, and here shall only be described the difference in mode of operation due to the radia¬ tion shield 3 according to the invention.
The radiation shield 3 stops the combustible gasses
and the smoke gasses rising from the foremost end of the hearth 10 and forces them backwards i -.the.firing chamber 11, where they are combined with the surplus air and the gasses rising from the rearmost end of . the hearth 10 and flow through the burning-out open¬ ing 8, and from here forward through the boiler and into the smoke pipes. In this manner is established an expedient, uniform discharge of gas from the ' .... hearth. At the same time, with the construction shown, a radiation of heat to the water running through the tubes 5 is achieved. A surprising and advantageous effect is that with the smoke and gas-tight, somewhat heat-insulating shield of ceramic material or the like, one obtains a surface with a surface tempera- ture which, for a water boiler, is relatively high.
The total effect is that these combustible gasses are ignited and can erefore .contribute to a pronounced increase in the thermal efficiency of the boiler. In a boiler with a radiation shield such as that sho n / in operation there have thus been achieved thermal efficiencies of around 9Q%. It should be added that the ignition of the combustible gasses can take place only when there is sufficient oxygen present in the firing chamber. It is expedient to introduce this oxygen through the inlet 9, whereby the air intro¬ duced is heated in a suitable manner when flowing out under the suspended .arch__2. Other forms of the inlet can be envisaged, but the secondary air must be in- troduced in such a way that it is mixed with the'com¬ bustible gasses under the radiation shield 3. Other embodiments of the invention than that shown In the drawing are conceivable, the essential point being that with a radiation shield, a firing chamber area
is established in which the temperature, including the radiation temperature, is considerably higher _... : than in normal water boilers, and at least so high that the ignition temperature of the combustible gas- ses is exceeded, and that this firing chamber area is established over that part of the hearth from which the main part of the combustible gasses are given off.
With generally known boilers having upwardly inclined radiation shields, the possibilities of varying boil¬ er loading are quite small, for example because de¬ creased loading gives increased 0 2 % in the gasses, thus resulting in less efficiency. Therefore, with hot-water boilers with upwardly rising radiation shields, one recommends a maximum load reduction of 50%."
With downwardly inclined radiation shields according to the present invention, it has been shown to be possible to reduce the load right down to 25% of full load while still maintaining the very high efficien¬ cy, the reason being that the efficiency, in fact, Increases slightly when the load is reduced. his is because the upwardly rising gasses cannot avoid being burned when the radiation shield is constructed as described above.
For the sake of good order it should be mentioned that by solid fuel is to be understood all kinds of solid fuel, for example wood, straw, pellets, peat, olive shells or briquettes.
Finally, the invention is not limited to the water-
Sty IPO
cooled tubes having a certain cross-section. Tubes with all possible cross—sections can be envisaged, for example round, triangular, oval or square.
OMPI
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