This invention relates to a boiler installation for the combustion of solid fuels, for example forest waste material,in the form of e.g. bark.and/or chips, peat pellets, coal etc., comprising a fire box located in connection to a heat medium portion and in said fire box a grate means, which from a fuel charge opening advances fuel through the fire box while the fuel is being combusted, from which fire box the flue gases flow to the heat medium portion and continue to a chimney, and at least one intake for adjustable supply of combustion air in the form of at least primary and secondary combustion air.

The utilization of forest waste material and other biologic material as fuel has increased, in spite of the absence of efficient boiler installations, which with high efficiency degree and great variations of the continuous load are capable to combust such forest waste material, which shows such disadvantages as for example highly varying quality and varying moisture content and a moisture content often amounting to 70% and even higher.

The object of the present invention, therefore, is to bring about such a boiler installation, which renders it possible to combust with high efficiency degree and completely forest waste material and other biologic fuels, which may have a high moisture content, without requiring these fuels first to be dried, which installation, besides, shall be manufactured and mounted in a simple way. This object is achieved in that the boiler installation according to the invention has been given the characterizing features defined in the attached claims.

The invention is described in greater detail in the following, with reference to the accompanying drawings, in which

• Fig. 1 is a lateral view, partially in section, of a boiler installation according to the invention,
• Fig. 2 is a view of the boiler installation, partially in section, substantially along the line II-II in Fig. 1,
• Fig. 3 shows schematically a modified embodiment of the stationary grate bed of the present boiler installation, in a lateral view,
• Fig. 4 is a longitudinal section on an enlarged scale between substantially the lines IV-IV in Fig. 3,
• Fig. 5 is on an enlarged scale a section substantially along the line V-V in Fig. 3,
• Figs. 6 and 7 are horziontal views of plates and, respectively, a bar comprised in the stationary grate bed shown in Fig. 3.

The present boiler installation for solid fuels comprises a fire box or furnace generally designated by 1, and in connection to said furnace 1 a heat medium portion,2, through which the flue gases are led to a chimney via a smoke pipe 3, and in which a medium flowing therethrough is evaporated or heated by means of the heat, which is generated by combustion of fuel in the furnace, where steam, water or air can be used as heat medium. The heat medium portion 2 may be of any known design and does not constitute an essential part of the present invention and, therefore, is not shown in detail in the drawings nor described.

In the furnace 1 a substantially horizontal grate means 4; is located which effects fuel migration through the furnace space,and which extends over the entire furnace space from a fuel charge dip or shaft 5 to an ash discharge screw 7 driven by a motor 6 and discharging the ash automatically. Said grate means 4, which hereinafter will be called scraper grate, comprises a movable feeding portion 4a, which is provided with scrapers or dogs 9, and a stationary scraper bottom 4b, on which the fuel is fed by the feeding portion 4a through the furnace 1 and combusted during said feed.

The feeding portion 4a of the scraper grate comprises two endless chains 8, which between themselves support the dogs 9 of the feeding portion, which dogs extend with full height between opposed sidewalls -10 of the furnace, as shown in Fig. 2. Said chains 8 with their dogs 9 run over two end rollers 11 and 12, which are located outside the furnace space proper, and with their upper strand run in guide grooves 13 in the sidewalls 10 of the furnace. One of the end rollers 11,12 is driven, for example the end roller 12 located at the discharge end of the scraper grate, as shown in Figs. 1 and 2. The said roller is driven by a motor 14 via a transmission 15 with a speed, which is adjusted automatically in response to the prevailing conditions. The end roller 12 is shown to be open and is mounted with its axle 14 in bearings 15. In a way similar to the end roller 12, also the end roller 11 can be designed and mounted.

Along the upper strand of the scraper grate the dogs 9 of the feeding portion are arranged to run upright edgeways on the scraper bottom 4b, which in the fire box space proper consists of a grate 16. At the embodiment shown in Figs. 1 and 2, the grate consists of longitudinal U-sections 17, which are arranged with their legs facing upward, and of longitudinal U- or E-sections 18 located on the upward facing U-sections and facing with their legs upward. The grate 16 rests with base irons 19 on transverse ridges 20,21 of a plate 22 located between the upper and lower strands of the scraper grate chains, which plate with a portion 23 thereof forms that portion of the scraper bottom which is located below the fuel charge dip 5 and constitutes the fuel feed portion of the scraper grate. The amount of fuel, which the scraper grate by means of its dogs 9 is permitted to take along- from the feed portion is controlled by means of a liftable and lowerable door24, which is located in the direction of movement of the scraper grate after the charge dip 5 above the scraper grate 4, and the position of which above the same thus detrmines the thickness of the fyel bed fed, which the scraper grate 4 takes along into the fire box or furnace space.

Of the transverse ridges 20 and 21, which are formed in the plate 22 located between the upper and lower strand of the scraper grate chains, the ridges 21 are provided with air passageways for supplying primary combustion'air from below to the fuel bed, which migrates slowly on the air permeable grate 16. The air passageways 21 preferably are provided at their sides with outflow apertures 25, which are provided with valves or flaps 26, which not only render it possible that the outflowing air can be directed so that it sweeps over the sides of adjacent ridges for cooling the same, but also such control of the air flow, that:ahe combustion is maintained on the intended level in the fuel bed along the entire length thereof. The primary air substantially is used for gasification (pyrolysis) and a certain combustion in the fuel bed to C0₂.

In the end walls 27 and 28 of the furnace space air intakes 29 are located for supplying secondary combustion air on different levels above the fuel bed, and the secondary air substantially is used for effecting combustion to C0₂, which delivers heat, in addition to the heat medium portion 2, also to said feed portion for successively drying fuel charged through the dip 5 while the fuel is being introduced into the combustion zone proper.

In the transition 30 of the furnace space to the heat medium portion 2, which transition in relation to the space in general is narrow and thereby acts as a speed-increasing throttling, additional air intakes 31 are located for supplying tertiary combustion air to said transition zone, in which flue gases coming from below are combusted completely without affecting the temperature at the beginning of the fuel bed.

For the supply of air to the air intakes 29 and 31 for the secondary and thertiary air and to the intakes of the primary air, the intakes are connected to air passageways 32, 33 located within and on the outside of the walls of the furnace space, whereby the combustion air is preheated prior to its participation in the combustion. Incoming air first flows upward through the internal passageways 32 and then to the different intakes through the outside passageways 33.

The walls 10,27 and 28 of the furnace space consist of sintered:aluminium.bloeks, which are assembled so as to form said internal air passageeays 32. The walls withstand high temperatures and have low thermal conductivity, whereby the temperature in the furnace can be maintained on a level as high as up to 2500°C, but at the same time the furnace walls consisting of sintered aluminium withstand great temperature variations.

These high temperatures also imply high requirements on the scraper grate 4 and especially on its dogs 9 and the sections 17 and 18 forming the grate 16. For this reason, the sections and at least the dogs 9 are made of silicon carbide, which also withstands temperatures as high as up to 2000 -2500°C.

In Figs. 3-8 the grate 16 of the scraper grate is shown by way of a modified embodiment, which comprises a plurality of substantially identical sections 14 arranged one after the other, which are supported by a frame 35, which is located on the ridges 20,21 and preferably consists of box beams 36, through which air can be passed for cooling purposes and thereafter be used as combustion air. Each such section 34 comprises a number of grate plates 37 located to the side of each other, which with their end 38, which in the feed direction of the fuel is the forward end and which in relation to the plate in general is offset by a distance corresponding to the plate thickness, rest against support irons 39 extending between the longitudinal beams of the frame, and which with their rear end are supported by the forward offset end 38 of the plates located behind. The plates 37 comprised in the first section 34 are supported at their rear end in said direction of movement by a support iron 40 located on the transverse beam of the frame, and additional support irons are provided between the ends of each section, as shown at 41 in Fig. 3.

The grate plates 37 are provided over their entire surface with holes 42, which are arranged in longitudinal rows with equal spaced relationship between the hole rows. At the embodiment shown in Figs. 3-8 one hole row is located in each joint between two plates 37 facing toward each other,,and the holes 42 are formed in the edge portions of these plates facing toward each other, as shown in Fig. 6. Above each such hole row a U-shaped grate bar 43 is located which consists of silicon carbide or corresponding material, which bar with its legs facing downward is supported by at least two distance members 44,45, which by means of pins 46 are located with play in one of the first and, respectively, last holes 42 in each hole row, as appears from Fig. 4, in such a manner, that the distance member 44 of each bar which is the rear distance member in the direction of movement of the fuel has a pin 47, which extends with play into a through hole 48 in the bar, while the distance member 45 of each bar which in said direction of movement is the forward distence member has a pin 49, which with play extends into a longitudinal slot 50 or groove in the lower surface of the bar, in order to permit a certain movement between the bar and the distance member. In Fig. 4 is shown-that the distance members 44 can be fixed both on the plate 37 and the bar 43, and the distance members 45 only on the plate by means of refractory cement 51, but the distance members 44,45 also can be arranged loosely in relation to both the plates and the bars.

The primary air flowing in through the air passageways 21, thus, flows upward through the free holes 42 of the plates located beneath the grate bars 43 and thereby is caused to first steep the inside of each bar and then the upper side of the plates 37, before it arrives at the fuel bed above the grate bars 43. Hereby an efficient continuous cooling of the grate 16 and simultaneously an efficient preheating of the primary combustion air is obtained. Due to said cooling of the grate, no other parts in the same except the grate bars 43 must be manufactured of material withstanding high temperatures, such as silicon carbide and corresponding material, and in spite thereof the grate is highly resistent even to temperatures as high as up to 2500°C in the combustion space.

At the embodiment according to Figs. 3-8 and Figs. 1 and 2 the dogs 9 of the scraper grate can be provided with projections (not shown), which extend downward between the grate bars 43 for scraping along the fuel and/or ash, which may be found between the grate bars 43. The space beneath the bars 43 in principle is maintained clean of fuel and ash by inflowing primary air.

At the end of the grate 16 in Fig. 3 a slide groove 50 is shown for transferring ash from the grate to the ash discharge screw 7.

Though not shown in detail, the boiler can be provided with an automatic ignition device and with means for recovering heat from outgoing flue gases which then can be utilized for heating the combustion air and pre-drying the fuel, especially when the fuel consists of bark and peat.

According to the principles on which the present invention is based, the fuel, which continuously and automatically is fed in through the charge dip 5 so that the fuel feed portion always is filled with fuel, is fed from this portion, in which the fuel is caused to commence to dry, in a controlled amount into the furnace, and is gasified and combusted successively, in such a manner, that the combustion temperature increases while the fuel migrates through the furnace. During its migration the fuel is subjected by the dogs of the scraper grate also to a certain stirring, which improves the air supply to the fuel and, thus, contributes to a very efficient and complete combustion being obtained. At the end, there remains only ash which is fed down automatically into the opening with funnel- shaped cross-section of the ash discharge conveyor. At the lower portion of the end wall 28 of the furnace a flap 51 of the same material as the walls 10,27,28 is pivotally suspended, by means of which the fuel can be stopped when for some reason it is not combusted completely.

The present invention is not restricted to what..is described above and shown in the drawings, but can be altered and modified in many different ways within the scope of the invention idea defined in the attached claims.