ES2540702B1 - SOLID FUEL BOILER - Google Patents

Abstract

The boiler comprises a solid fuel tank, a dispenser and a combustion chamber, the combustion chamber has an internal trunk-conical wall supported by the upper face of a grill that is hollow and supports solid fuel, and includes holes in its lower face through which a secondary air flow is introduced into the combustion chamber, characterized in that the internal wall of said chamber and the upper face of the grill form a conical volume of fuel with a variable reaction area depending on the primary air flow introduced into the combustion chamber, and the regulation of the secondary air flow that is provided through the grill is done based on the amount of oxygen in the exhaust gases.

Description

DESCRIPTION

Solid fuel boiler.

Object of the invention 5

The present invention encompasses in the field of boilers that run on solid fuels, such as biomass, coal, wood, etc.

Said invention essentially proposes a boiler that uses the internal trunk-conical wall 10 of the combustion chamber and the upper face of the grill to form a conical volume of solid fuel with a fuel reaction area that can vary depending on the flow of primary air that is introduced into said combustion chamber.

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On the other hand, the regulation of the secondary air flow is achieved, which is introduced into the combustion chamber through holes made in the grill, according to the amount of oxygen existing in the combustion exhaust gases.

Background of the invention

In reference to the state of the art, it should be mentioned that different types of boilers are known and marketed for both domestic and industrial use.

Boilers for burning solid fuel generally comprise a silo or fuel tank whose bottom there is a doser that delivers solid fuel to a combustion chamber.

At the bottom of the combustion chamber is a grill on which solid fuel is burned. Said grill is also capable of retaining and discharging the ashes 30 towards a home located at the bottom of the combustion chamber.

Following the home, in fluid communication with it, a heat exchanger is included. The exhaust gas from the combustion generated passes through said exchanger transferring heat to the water for later use, for example, in heating systems, domestic hot water, etc.

To carry out the combustion of the solid fuel deposited on the grill it is necessary to supply said combustion chamber with a certain amount of air.

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The combustion technology currently used in solid fuel boilers includes a gasification (incomplete combustion) phase of the fuel arranged on the grill, using a primary air flow that is introduced through the upper part of the combustion chamber. say, above the solid fuel deposited on the grill. Four. Five

In a subsequent phase of total combustion developed on the home once, through the grill, the amount of air needed to complete the combustion of the gas generated in the previous phase is provided.

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In some boilers, the grills involved in said total combustion phase are hollow and have a plurality of holes through which said secondary air flow is injected to complete the combustion of the fuel. Examples of these types of grills are those shown in patent documents: WO 201227805, published on March 8, 2012; EP 2314916, published on April 27, 2011; and GB 2159938, 5 published on December 11, 1985.

However, these known solutions do not show that the secondary air flow to be injected can be controlled, guaranteeing the complete combustion of the material effectively and efficiently. 10

Description of the invention

In view of the foregoing, the present invention relates to a solid fuel boiler. fifteen

The boiler comprises a fuel tank in whose lower part a dispenser is arranged that drives the solid fuel into a combustion chamber.

Both solid fuel and a primary air flow penetrate the upper part 20 of said combustion chamber.

On the other hand, the combustion chamber has an internal trunk-conical wall and is supported by the upper face of a grill. Said grill is hollow and includes a plurality of holes in its lower face through which a flow of secondary air is introduced into the combustion chamber.

Likewise, the grill supports the solid fuel, being arranged on a home that has fluid communication with a heat exchanger. Said heat exchanger is where the energy content of combustion exhaust gases 30 is used, giving heat to the water, which will be used in heating systems, domestic hot water, etc.

The boiler is characterized in that the internal wall of the combustion chamber and the upper face of the grill form a conical volume of solid fuel. 35

The conical shape of the solid fuel disposed between the internal wall of the combustion chamber and the upper face of the grill makes the fuel reaction area variable, positioning at a different height, depending on the primary air flow that is introduced into said combustion chamber. 40

On the other hand, the regulation of the secondary air flow, provided through the holes in the grill to complete the combustion of solid fuel, is done based on the amount of oxygen in the exhaust gases.

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Conditioning the amount of air flow secondary to the presence of oxygen in the exhaust gases allows to achieve complete combustion of the solid fuel in an effective and efficient manner.

That is, in this way only the exact amount of secondary air that is required at any time would be injected to make the fuel completely combustion.

Description of the figures

The present specification is complemented with a set of figures, illustrative of the preferred example, and never limiting the invention.

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Figure 1 represents a front sectional view of the boiler.

Figure 2 represents a sectional side view of the boiler.

Figure 3 represents an enlarged sectional view of the combustion zone of the boiler of Figure 1.

Figure 4 represents a bottom perspective view of the grill included in the boiler of Figure 1.

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Figure 5 represents a perspective view of the turbulators included in the heat exchanger of a boiler variant of Figure 1.

Detailed statement of the invention

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The present invention is a solid fuel boiler for use in heating systems, domestic hot water, etc.

The solid fuel feed (3) to the boiler, for example, pelletized biomass in the form of pellets, part of a silo or fuel tank (1) included in the boiler itself.

The loading of said fuel tank (1) can be carried out manually, through the emptying of solid fuel bags (3), or automatically, through the discharge of fuel from another silo of larger dimensions by means of an auger system or a pneumatic system (not seen in the figures).

To detect the need to fill the fuel tank (1), a sensor (not seen in the figures) can be placed inside it that gives visual and / or audible indications when the amount of solid fuel (3) available in said tank is less than 35 a default value.

As can be seen in Figures 1 and 2, the dosing of the solid fuel (3) into the combustion chamber (4) is carried out by means of a doser (2), preferably of the screw type, driven by a gearmotor (15). 40

Preferably, the dispenser (2) is provided with a flame arrester system (14) to prevent the flame backing into the fuel tank (1).

Said flame cutter system (14) consists of a chopping board (14.1) operated by a device (not detailed in the figures) with return spring by means of which it is ensured that, in the event of an electrical failure, it is closed. The closure of the chopping board (14.1) is carried out in case of shutdown or detection, by means of a probe (not shown in the figures), of high temperature in the feed duct (16).

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The solid fuel (3) penetrates into said combustion chamber (4) from its upper part. Preferably, the solid fuel supply (3) is commanded by an infrared probe (10) that detects the level of the upper face of the solid fuel (3) inside the combustion chamber (4).

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Also a primary air flow (5) penetrates said combustion chamber (4) at its upper part. This flow will be conditioned to the required generation power.

For its part, the combustion chamber (4) has an internal wall (4.1) trunk-conical and is supported by the upper face (6.1) of a grill (6). 10

The solid fuel (3) provided by the upper part of the combustion chamber (4) is retained between the internal wall (4.1) of the combustion chamber (4) and the upper face (6.1) of the grill (6), conforming a conical volume of said solid fuel (3).

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Said conical shape of the solid fuel (3), formed by being disposed between the internal wall (4.1) of the combustion chamber (4) and the upper face (6.1) of the grill (6), causes the reaction area of said fuel is variable, positioning at a different height, depending on the primary air flow (5) that is introduced into said combustion chamber (4). twenty

The combustion chamber (4) can also have a duct (17) from which a stream of hot air is provided on the solid fuel (3), allowing its initial ignition. Once the fuel is ignited, it is self-contained.

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The grill (6) supports the solid fuel (3), which is arranged on a home (8). In this way, the evacuation of the generated ashes is carried out towards the home (8).

On the other hand, the grill (6) is hollow and includes a plurality of holes (6.3) in its lower face (6.2) through which a secondary air flow (7) is introduced to complete the combustion of solid fuel (3).

The structural configuration of the grill (6) allows the correct mixing of the secondary air flow (7) with the primary air flow (5). 35

Likewise, the contribution of the secondary air flow (7) through the inside of the grill (6) allows it to cool, reducing its service requirements, which prolongs its useful life.

Preferably, see figure 4, the grill (6) comprises a plurality of hollow bars (6.4) 40 arranged in parallel and with such separation that it allows to evacuate the ashes generated towards the home (8).

The regulation of the secondary air flow (7) that is provided through the holes (6.3) of the grill (6) is based on the amount of oxygen in the exhaust gases.

Preferably, the secondary air flow (7) is regulated by a lambda probe (11) that measures the concentration of oxygen in the exhaust gases at the outlet of the boiler.

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Likewise, a butterfly valve (12), commanded by the lambda probe (11), can be provided in the secondary air intake (13) to regulate its flow.

The home (8) constitutes the area over which the flame is generated and the ashes are collected.

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Access to the home (8) can be done through a door (18), where the ash extraction can be carried out and the grill (6) removed in case of disassembly.

Additionally, the door (18) can include a sight glass (19) through which the presence of flame is detected. A presence sensor (not shown in the figures) prevents the boiler from being switched on with the door (18) open, in addition to starting the boiler off if said door (18) is opened.

Preferably, both the home (8) and the combustion chamber (4) are coated with a refractory material, for example, concrete, to prevent thermal losses. fifteen

The home (8), in addition to the coating of refractory material, could be wrapped in a water jacket (8.1), which minimizes the thermal losses of the combustion exhaust gases in its path.

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The home (8) constitutes a transition zone between the combustion zone and an exchange zone. The home (8) has fluid communication with a heat exchanger (9), where the energy content of the combustion exhaust gases is used.

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In this sense, the combustion exhaust gases generated enter through the lower zone of the heat exchanger (9).

Preferably, said exchanger (9) is of the pyrotubular type comprising a plurality of parallel tubes (9.1) through which said combustion gases pass, 30 while the water to be heated flows out of said tubes (9.1). In addition, said exchanger (9) can be placed in series with the water jacket (8.1) of the household (8).

Preferably, an axis (9.2) with a plurality of turbulators (9.3) is arranged inside each tube (9.1) to optimize heat transfer by generating turbulence on the combustion exhaust gases. That is, the thermal exchange between said gases, which circulate inside the tubes (9.1), and the water, which circulates outside said tubes (9.1) is maximized.

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As can be seen in Figure 5, the turbulators (9.3) constitute semicircular shaped plates welded in pairs to the axis (9.2). The pairs of turbulators (9.3) are arranged equidistant along the axis (9.2) facing each other obliquely. Its geometric configuration not only allows to optimize the heat transfer but also facilitates the internal cleaning of the tubes (9.1). Four. Five

On the other hand, the amount of air necessary to carry out the combustion of the solid fuel, that is to say the primary (5) and secondary (7) air flows, is supplied by an exhaust fan (15).

Preferably, said extractor fan (15) is arranged at the outlet of the heat exchanger (9). Specifically, after the lambda probe (11) and before the connection to the chimney (not shown in the figures) of the boiler.

To facilitate the boiler shutdown, primary solenoid valves (21, 22) with spring can be included in the primary (20) 5 and secondary (13) air intakes, which are activated to start the boiler and, in case of shutdown or emergency situation, they are closed by the action of the spring cutting the supply of combustion air, and therefore, facilitating the shutdown of the boiler.

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In turn, the boiler could have other safety devices, such as a thermostat (23) with manual reset and an additional exchanger (not shown in the figures).

The thermostat (23) is included inside the exchanger (9), activating when it exceeds 15 the maximum setpoint temperature (90ºC).

For its part, the additional exchanger is coupled to the exchanger (9) and has a water inlet from the network commanded by a thermocontact (not seen in the figures) that is activated when a maximum temperature is exceeded, and an outlet directed to 20 drain. This exchanger allows the residual power of the boiler to dissipate in the event of an electrical failure.

Claims (14)

1. Solid fuel boiler comprising a fuel tank (1) in the lower part of which a dispenser (2) is arranged that drives the solid fuel (3) 5 into a combustion chamber (4), said solid fuel (3) and a primary air flow (5) penetrates said combustion chamber (4) at its upper part, the combustion chamber (4) has an internal conical trunk wall (4.1) and is supported by the upper face (6.1) of a grill (6), the grill (6) is hollow and includes a plurality of holes (6.3) in its lower face (6.2) through which a secondary air flow 10 (7) is introduced into the chamber of combustion (4), said secondary air flow (7) is regulated according to the amount of oxygen in the exhaust gases, the grill (6) supports the solid fuel (3), which is arranged on a home ( 8) that has fluid communication with a heat exchanger (9), where the co is used energy content of the combustion exhaust gases, characterized in that the internal wall (4.1) of the combustion chamber (4) and the upper face (6.1) of the grill (6) form a conical volume of solid fuel ( 3) with a variable reaction area depending on the primary air flow (5) that is introduced into said combustion chamber (4).  twenty 2. Solid fuel boiler according to claim 1 wherein the solid fuel supply (3) to the combustion chamber (4) is commanded by an infrared probe (10) that detects the level of the upper face of the fuel. solid (3) inside the combustion chamber (4).  25 3. Solid fuel boiler according to claim 1 wherein the secondary air flow (7) that flows through the holes (6.3) of the grill (6) is regulated by a lambda probe (11) that measures the oxygen concentration in Exhaust gases 4. Solid fuel boiler according to claim 3 wherein a butterfly valve 30 (12), commanded by the lambda probe (11), is arranged at the inlet (13) of the secondary air to regulate its flow. 5. A solid fuel boiler according to claim 5 wherein the grill (6) comprises a plurality of hollow bars (6.4) arranged in parallel and with such separation that allows the ashes generated towards the home to be evacuated (8). 6. Solid fuel boiler according to claim 1 wherein the solid fuel dispenser (2) is of the screw type auger.  40 7. Solid fuel boiler according to claims 1 or 6 wherein the solid fuel dispenser (2) is provided with a flame arrester system (14). 8. Solid fuel boiler according to claim 1 wherein the combustion chamber (4) and the home (8) are coated with a refractory material. Four. Five 9. Solid fuel boiler according to claim 8 wherein the home (8) is wrapped in a water jacket (8.1) that minimizes thermal losses of combustion gases. 10. Solid fuel boiler according to claims 1 and 9 wherein the heat exchanger (9) is placed in series with the water jacket (8.1) of the household (8). 11. A solid fuel boiler according to claims 1 or 10 wherein the heat exchanger (9) is of the pyrotubular type, comprised of a plurality of tubes (9.1) through which the combustion gases pass. 12. Solid fuel boiler according to claim 11 wherein inside each tube (9.1) an axis (9.2) with turbulators (9.3) is arranged to optimize heat transfer. 13. Solid fuel boiler according to claims 1 and 3 wherein at the outlet of the heat exchanger (9), after the lambda probe (11), an exhaust fan (15) is provided that guarantees primary air flows (5) and secondary (7) to carry out the combustion of solid fuel (3). 14. Solid fuel boiler according to claim 1 wherein the solid fuel (3) used is biomass.  twenty