UA136061U - BOILER FOR COMBUSTION OF FULL BIOMASS BALTS - Google Patents

Abstract

A boiler for burning full biomass bales consists of a combustion chamber equipped with a door for at least one flue gas heat exchanger, a flue channel located in the upper section of the combustion chamber, and having a flue gas inlet located on the side of the combustion chamber opposite the side on which at least one air intake for combustion. The combustion chamber has a cylindrical shape, and the doors are round, located along the entire section of the boiler. A smoke channel separated by a heat-resistant arch made of sheet metal and the ceiling of the combustion chamber. The air intake for combustion is connected to the source of air for combustion, connected to the combustion chamber by a pipe equipped with a distributor and made with the possibility of splitting into a primary air pipe and a secondary air pipe.

Description

The proposed utility model relates to heating equipment, in particular a boiler for burning biomass, in particular a boiler for burning full bales of biomass, a boiler containing a combustion chamber and at least one heat exchanger.

Currently, there are many biomass burning plants, as well as a number of ways to burn biomass. Such installations also include boilers burning full bales of straw.

Such installations can be divided into installations with a device for dosing straw from a bale before loading into the combustion chamber and those that allow loading full bales of straw into the combustion chamber.

The above-described installations may also include an installation intended for burning mass of plant origin, described in patent document C5 228635. The installation consists of a pressing chamber connected to a bunker for storage of bulk fuel.

The pressing chamber is equipped with a screw press mounted on a hollow shaft. The chamber is connected to the air intake and built into the combustion chamber together with the outlet of the pressing chamber. One of the main disadvantages of this installation is that the screw press makes it easier to load a mass that consists of small particles, but not easier to load, for example, a full bale of straw.

Application C2 RM 2001-1178 describes a method of burning biomass that is compressed into large bales and an installation used for the burning method. This method consists in the fact that the longitudinally placed bale is transported by means of a horizontal conveyor from the storage hopper to an inclined bridge that returns to the horizontal plane. The bridge then returns to the vertical plane again and the sliding leg of the bridge grip holds the lower surface of the bale. The loading chamber then moves over the inclined bridge, the sliding foot of the bridge gripper moves the bale held vertically upwards into the loading chamber, where the vertical conveyor grippers built inside grab the inserted bale.

Then, the loading chamber with the trapped bale, moving over the vertical shaft of the combustion chamber, lowers the trapped bale vertically into the shaft of the combustion chamber, where the lower surface touches the aeration mechanism. The installation used in this method consists of a loading line and a boiler for combustion, which is equipped with an aeration mechanism and is connected to a heat exchanger. The disadvantage of this installation is its large size, complexity and high cost.

Another plant that can burn full bales of straw is known from patent C 16473. This plant is equipped with a suction fan for flue gases and an exhaust pipe for flue gases. The combustion chamber is limited by a partition and a back wall and is located inside a casing consisting of a foundation, a left wall, a right wall and a ceiling.

In addition, the corresponding pre-chamber is separated by a front wall with an opening and a partition, as well as a left wall, a right wall and a ceiling, its back wall is equal in height to the height of the casing and extends to the ceiling itself, where the back wall is equipped with openings for flue gases. The bulkhead tapers in its lower part and is provided with one or more pipes attached (under the bulkhead) to the right and left gap walls. In addition, the movable grate is located above the surface of the ground obliquely from the front wall with an opening to the back wall. The movable grate partially protrudes into the combustion chamber, and there is a gap between the upper surface of the movable grate and the lowest pipe for feeding straw into the combustion chamber. The prechamber space is closed by a movable grate in its lower part, but the combustion chamber in its lower part is fenced off by a movable grate just behind the partition. At the level of the foundation there is an ashtray located on the back wall and a chimney with an opening for flue gases.

A method of burning bales is also known (patent C7 303224). This patent describes the combustion of biomass bales in a boiler with adjustable combustion air intake into the combustion chamber using a blower or flue gas suction fan. Air is supplied to the combustion chamber by at least one nozzle, the position of which can be changed in the vertical plane. Combustion air, throughout the burning time, is supplied tangentially to the top surface of the bale being burned, and the flue gases will be exhausted relative to the air supplied to the interior. The boiler is equipped with at least one nozzle for sucking air for combustion, which is directed away from the wall of the combustion chamber at the level of the upper surface of the bale. The nozzle can rotate about its horizontal axis, and the outlet is located opposite the nozzle. The disadvantage of this boiler is the fact that the mechanism of the main air intake is quite complex, while the advantages arising from such a design do not enhance the overall useful value of the boiler as a whole.

Patent C2 17061 describes a combustion chamber for burning biomass and coal, which is additionally equipped with a device for feeding full bales of straw into the combustion chamber and a screw conveyor for removing ash and other non-combustible particles from the chamber. The combustion chamber is divided into the first and second combustion sections between the movable grate in the lower part, the ceiling in the upper part, the front and back walls, and the left and right side walls. These walls consist of water-cooled pipes, and the ceiling, by the curve, is a continuation of the front wall, its ceiling pipes run upwards at an angle to the rear wall and are connected to the upper chamber of the rear wall, and the front wall is provided with an opening for feeding straw bales respectively to which the movable grate is inclined from the front wall to the rear wall, and behind the movable grate, the first chamber of the inclined wall is connected to the rear wall, which is composed of pipes and ceramic materials. These pipes go up at an angle and are connected to the second chamber and, the chamber (with vertical pipes) is attached to the ceiling pipes. In addition, supporting tubes with spaces between them are connected to the lower side of the second chamber and to the front wall, and these tubes carry two ceramic blocks that are placed in their upper part and cover the entire width of the combustion chamber, thereby forming a through hole between the first section combustion chamber below the inclined wall and ceramic blocks and the second section of the combustion chamber above the ceramic blocks and inclined wall. The opening is equipped with a first ceramic partition located behind the vertical pipes in the direction of the back wall and attached to the ceiling. This partition goes vertically down in the direction of the inclined wall and protrudes into the second section of the combustion chamber. Another ceramic partition is located closer to the back wall. It goes from the inclined wall vertically upwards in such a way that its upper edge ends right next to the lower edge of the first ceramic partition, thus forming a smoke channel between the second ceramic wall and the back wall. The smoke channel is connected to the flue gas opening in the back wall. The disadvantage of this design is that it does not have any auxiliary device for dosing individual straw bales.

The patent OK 621286 describes the method of burning full bales of straw and the installation used in the method. The method is based on burning full straw bales without prior separation. Straw bales burn from one of their ends and the burning process is continuous. This is achieved by feeding individual bales of straw into the combustion chamber, one at a time, using a hydraulic piston. The power of the boiler depends on the speed at which the piston pushes the bales of straw into the combustion chamber. The design of the boiler, again, is relatively complex and therefore expensive.

From the above, it is clear that the current state of this problem in the industry has a number of disadvantages, the most important of which is the relative complexity of the design of the boilers that have been described so far. In addition, despite the complexity of the design, there is no radical increase in the overall useful value of the boiler as a whole. Another disadvantage of most boilers known so far is their large size.

The task of the proposed useful model is to create an easy-to-use and inexpensive design of the boiler, which will contribute to the efficient burning of full bales of straw, corn and grass, while, at all emission limits, which are always present, the dosage of these masses consists in one filling of the combustion chamber .

These shortcomings are largely eliminated in the proposed useful model.

The problem is solved by the fact that a boiler for burning full bales of biomass, consisting of a combustion chamber equipped with a door of at least one flue gas heat exchanger, a flue channel located in the upper section of the combustion chamber, and having a flue gas inlet located on the side of the combustion chamber , on the opposite side, on which at least one combustion air intake is located, according to a useful model, the combustion chamber is cylindrical in shape, and the door is circular in shape, located throughout the boiler cross-section, while the smoke channel is separated by a heat-resistant sheet metal arch and a ceiling combustion chamber, and the air intake for combustion is connected to the source of air for combustion, connected to the combustion chamber by a pipe equipped with a distributor and made with the possibility of splitting into a primary air pipe and a secondary air pipe.

The primary air pipe is connected to at least one primary air nozzle located in a fixed horizontal plane at the lower level of the rear side of the combustion chamber, and the secondary air pipe is connected to at least one secondary air nozzle located in a fixed horizontal plane below the heat-resistant arch on the upper levels of the back side of the combustion chamber.

The primary air pipe is equipped with a regulating valve for primary air and the secondary air pipe is equipped with a regulating valve for secondary air.

Control of these two-way dampers ensures efficient combustion with low flue gas emissions.

The boiler is equipped with a suction fan for flue gases to ensure adjustable draft for the entire burning period.

The combustion chamber is cooled, ideally, by water. This design is the most beneficial from the point of view of reducing the corresponding production costs and from the point of view of high-quality burning of stem plants, which requires a lower burning temperature compared to burning wood. The design is even simpler and the entire boiler is even cheaper if the door of the combustion chamber is round and does not cool. In addition to this, it is advantageous if at least part of the combustion chamber is provided with a heat-resistant insulating material that ensures an optimal temperature in the combustion chamber.

A useful model is presented in the drawings, in which:

In fig. 1 shows a view from the side of a boiler for burning biomass with a partial sectional view;

In fig. 2 shows a front view of a boiler for burning biomass;

In fig. C shows a side view of a boiler for burning biomass with a heat exchanger located above the combustion chamber;

In Fig. 4 shows a side view of a biomass boiler with a heat exchanger placed next to the combustion chamber.

The boiler for burning full bales 20 of biomass - straw (Fig. 1, Fig. 2) consists of a combustion chamber 1 and a heat exchanger 2.

The front side 17 of the combustion chamber 1 is equipped with a door 15 located along its entire cross-section.

In the upper part of the combustion chamber 1 there is a smoke channel 3, separated by a heat-resistant sheet metal arch 6 and the ceiling 19 of the combustion chamber 1.

The inlet 24 for flue gases C is located on the side of the combustion chamber 1, which is the opposite side to the intakes 25, which supply air for combustion to the combustion chamber 1.

Combustion air intakes 25, which include primary air nozzles 14 and secondary air nozzles 23, are connected by pipes 26 to a source 13 of combustion air. Before entering the combustion chamber 1, the air for combustion is divided into two streams - the stream of primary air and

From the flow of secondary air. For this reason, the pipe 26 is equipped with a distributor 27. Then the pipe splits into a primary air pipe 28 and a secondary air pipe 29. The source of combustion air 13 is a fan.

The primary air pipe 28 is connected to the primary air nozzles 14, which are located in a fixed horizontal plane at the lower level of the back side 18 of the combustion chamber 1.

The primary air pipe 28 is equipped with a regulating valve with a drive for primary air 21.

The secondary air pipe 29 is connected to the secondary air nozzles 23, which are located in a fixed horizontal plane below the heat-resistant arch b at the upper level of the back side 18 of the combustion chamber 1. The secondary air pipe 29 is equipped with a regulating valve with a secondary air drive 22.

Heat exchanger 2 is a horizontal heat pipe heat exchanger. It is located (Fig. 3) above the upper section of the combustion chamber 1, equipped with two exhaust channels 8, 10 and connected through the rotary chamber 7 with the combustion chamber 1. The rotary chamber 7 is connected to the smoke channel 3. The heat exchanger 2 is equipped with a suction fan for flue gases 12.

The heat exchanger 2 can also be located next to the combustion chamber 1 (Fig. 4).

Combustion chamber 1 is cylindrical and equipped with a non-cooling round door 15. Combustion chamber 1 is completely cooled by water.

The back wall 18 of the combustion chamber 1 is covered with a heat-resistant insulating material 5 or a fire-resistant lining. The ceiling 19 of the combustion chamber 1 is covered with heat-resistant insulating material 4 or fire-resistant lining.

In the middle of the back side 18, there is a door for kindling 16.

In addition, the boiler is equipped with a thermostat (not shown), which reduces the power of the boiler when the set water temperature is reached. The boiler is additionally equipped with a temperature limiter (not shown) and a safety valve (not shown) to prevent overheating and exceeding the maximum pressure.

The boiler for burning 20 full bales of biomass works as follows: First, a full bale of 20 straws (it is advantageous if the bale has a cylindrical shape) is inserted into the boiler. Then the door 15 and the combustion chamber 1 are closed. At the same time, the source 13 starts pumping air for combustion, and 60 bales 20 of straw are ignited through the ignition door 16.

Flue gases from the combustion chamber 1 exit through the flue channel C through the first rotary chamber 7 into the first exhaust channel 8 of the heat exchanger 2 and then through the second rotary chamber 9 into the second exhaust channel 10 of the heat exchanger 2, from which they are discharged by the suction fan for flue gases 12 through the outlet for flue gases 12 into the chimney (not shown).

The source 13 of air for combustion changes its speed during the combustion process depending on the volume O: in the flue gases. Thus, the suction fan for flue gases 12 at the outlet for flue gases 11 maintains a negative pressure in the combustion chamber 1.

When the straw bale 20 burns, the door 15 in the combustion chamber 1 is opened, and another straw bale 20 is inserted into the combustion chamber 1, which is usually ignited by the previous burned bale 20. Then the whole burning process is repeated.

If necessary, the ash from the combustion chamber 1 is removed manually through the door 15 using an ash scraper and collected in an ashtray (not shown).

The proposed boiler can be used for burning biomass, in particular biomass in the form of bales, especially if the biomass is presented in the form of large bales of straw or hay and has a cylindrical shape.

Claims (5)

USEFUL MODEL FORMULA 1. A boiler for burning full bales of biomass, consisting of a combustion chamber equipped with a door of at least one flue gas heat exchanger, a flue channel located in the upper section of the combustion chamber, and having a flue gas inlet located on the side of the combustion chamber opposite the side, on which there is at least one air intake for combustion, which is distinguished by the fact that the combustion chamber (1) has a cylindrical shape, and the door (15) has a round shape, located along the entire section of the boiler, while the smoke channel (3) is separated by a heat-resistant arch ( 6) from sheet metal and the ceiling (19) of the combustion chamber (1), and the intake (25) of combustion air is connected to the source (13) of combustion air connected to the combustion chamber (1) by a pipe (26), equipped with a distributor (27) and made with the possibility of splitting into a primary air pipe (28) and a secondary air pipe (29). 2. The boiler according to claim 1, which is characterized in that the primary air pipe (28) is connected to at least one primary air nozzle (14) located in a fixed horizontal plane at the lower level of the rear side (18) of the combustion chamber (1) , and the secondary air pipe (29) is connected to at least one secondary air nozzle (23) located in a fixed horizontal plane below the heat-resistant arch (6) at the upper level of the back side (18) of the combustion chamber (1). 3. Boiler according to any of claims 1, 2, which is characterized by the fact that the primary air pipe (28) is equipped with a regulating valve for primary air (21) and the secondary air pipe (29) is equipped with a regulating valve for secondary air (22). 4. A boiler according to any of the previous items, which is characterized by the fact that it is equipped with a suction fan for flue gases (12). 5. Boiler according to any of the previous items, which is characterized by the fact that the combustion chamber (1) is cooled. yah KZUch go h z g GU z s I sh - She I - V y Zoya B U 2 KZ Z Hall Zh v ; and I don't know - мм и и KI Mosk uk yuyu te Y KE U ii ii Monenenya E sv, иЙХ и и И Z . ek, okon SNACKS WE Ku Ek : Mei A kkkkKyuKeH KK Neon nn NN ZM NEK SCHE i. Seams know how to cut meat - Z Z pk niy Z XXX MU U shchi x td DM uk KK KK MV Pezhk x U : xx Ху he KK EZ 5 Z ОХ, I and ЯК. ; y ih o Ж E oon AN A AK AV VYM |: EKZ Y yi EV t deU Vk ks Kk kn ZOZ dai » :chЩ ns i kh nena nn ys Ko Zhe ten che ZKU xx OM Ye 5 SHE I ih I na same z y B x y z lym, k z ; By UK Ye ryudkoreyutof ore fosonu ke KK yunm ye y ShK teh: Z IZ i; dkkyumyum as p I I nn MYH x t Y ih Х y more and SHE SHE I still х х TUYA o SKK so Bk oh B. 7 ik; 5 y U KMkhMyu Mo dednnnkk DUtyuknnkhikh chE go hek, ZK. ЕХ ч Ж poet Z r oy She ki denno iz Z. s MOZH yan MM tn, KAH I і і MK tk de dec. sok, EE and still NK kn V, t S zhom zbo sho vah same | In the housing complex; her | ze V en shE; them I: Z M SMAK dk oi y shiny M «xx KO v v v Mf eh ke Be U GK ЖЖ «АH ZMK GOD sa still ev ii what their Z Code I same EE Ede Y i Z U ЖХ s ИМ В and still them M seym kk zh i Z Z Z Ko eh ek ko dk ZHK Zhe fe Jacques ZV a, 5 ZKU Na i eh MV I, M X EE Dan : K: In PC o ZK g: still SHY shi s she in KE g ische a same v i i i: : su sh -- same ro . ZK Z Z i Z ri ZY her BK a EK luk du zho still Z sya yi KZ E I and kny, zhk she: Ka i Kz i Nkh TSO MM b teh Z BEH in Her shk zh ko dike that Kn Me y: sia KK. NKU I and MM and BBZ 1; x y Zk y Me Ko y o a You VV ZHE SE y U x zhy y z. Кх КИ х ИЗ х More o - DAYS WE K5 at 1:35 3 be SHO v OK V Kk a KK KK x KU i dk le AKAKAKLALAAAAAAAAAAAALAATKAH om I be eh son MK x t m EK 8 X y Z Mak x with Ku vyy With s in VV her 5 oyu Z z zh she i y in Z Z za zvo i S sa Her ak I Eh i y Ka Y zh As Jhe B Sh- KZ 7 4 i8 k 4425 in Fig. 1 km V o zh y J o im y v: - B hey y Veny Х alle Ho s dennunnnnuyu vo OVK E ee KE Z ih hu ih sokhkhkhkhkhk kr E X s vovni I zh-- U U v. From KO sch. In Me zh i SCHE "NKU ky ey oh a zhh V I My SU yaz KU I E Z OO Her i g z Z already Z i V i i i ; From vk to shop ee koe 5 Ka UNO and yaki eh z y Y pe 3 r M in Z V is Zh 7 AJ ZK in Z. z in Ki Kz KAK KUM KKU MUKU UM; nn: Uk: KZ x. KKU she yi nin z z --- z I KZ U I xx Z EK KO U 5 IZ K Ku I KZ i I IZ I i KZ KZ BUYA Ku i B VK ENN OK EZ Z i AH Z X x still I. оо вн Я " the same as Kai 5 x shchi in M, pkhkkkkkkkkkkkkkkKKH same. shkh KB poooovasya for Ж. Fig. 7 th 4. | y Ko y ey AK 5 x : goes M eto V eV S. with article 5 on ze with KYA , | And listen to me, I'm in the zone, he's still her Fig. 4