ITVI20100042A1 - COMBUSTION SYSTEM - Google Patents

Description

PELLET AND / OR BIOMASS COMBUSTION EQUIPMENT.

DESCRIPTION

The present invention relates to a combustion apparatus of the improved type for stoves and thermo-stoves fed with pellets and / or biomass.

Different types of combustion apparatuses are known in which the adjustment of the parameters is carried out only a priori, and precisely in the laboratory test phase by establishing, for example, the maximum temperature admissible by the smoke sensors or the static and dynamic depression suitable for ensuring good combustion.

Basically, the adjustment is therefore configured as an initial calibration on the basis of pre-established parameters.

However, when there are changes in the environmental conditions and in the elements that make up the combustion, it is not possible to correct these parameters set upstream.

This fact leads to the inefficiency of the combustion apparatus of the stove / boiler, since the parameters estimated upstream do not comply with the parameters according to which the combustion apparatus would be efficient.

In fact, to make the necessary changes, specialized technical personnel must intervene who, acting in the electronic control and programming system, modify the parameters on the basis of programming logics initially established by the manufacturer.

In combustion apparatuses of the known type it therefore becomes laborious to modify the pre-set operating values of the depression in the combustion chamber, the temperature of the fumes and the reference ambient temperature when changes occur in the environmental conditions that involve the need to modify the aforementioned values.

This laboriousness of intervention to modify these parameters often means that the user, also to avoid expenses, omits carrying out the modifications with consequent inefficiency of the equipment and an increase in atmospheric pollution and operating costs.

To try to eliminate the aforementioned drawbacks, combustion apparatuses have been devised equipped with depression sensors, flue gas temperature sensors and ambient temperature sensors that can be managed, during the operation of the combustion apparatus itself, by means of a feedback carried out through an electronic control unit.

Patent documents relating to this latter implementation are, for example, patent application WO 2006/120717 A1 or patent application EP 1 219 899 A1 or patent application DE 10 2007 055168 A1.

According to these patent documents, the type of control that is carried out concerns the individual operating parameters through detection with sensors and individual variation curves of these parameters. In other words, the individual parameters are adjusted by means of feedback control of their compliance with the set reference values.

A limitation found in these devices is due to the fact that each parameter is adjusted independently from the others.

Consequently, in these combustion apparatuses the regulation of the depression in the combustion chamber detected by the depression sensor occurs in a totally independent way with respect to the temperature of the fumes detected by the temperature sensor of the fumes themselves and to the ambient temperature detected by the ambient temperature sensor.

This implies a combustion apparatus performance that is not always optimal.

International patent application WO 2006/120717 A1 deals with an air-gas regulation system applied to a radiant tube heating system. This regulation system is not applicable to pellet and / or biomass combustion equipment.

Patent application DE 10 2007 055168 A1 deals with a method of regulating the air-fuel mixture according to the quantity of water measured at the exit of the combustion chamber.

This type of regulation does not work in pellet and / or biomass combustion equipment, because the fuel regulation is carried out differently in pellet and / or biomass equipment. In fact, liquid and gaseous fuels have a known and stable physical mass and calorific value, while pellet and / or biomass combustion apparatuses have a variable physical mass and calorific value. Consequently, the solutions adopted for the aforementioned documents cannot be so with regard to pellet and / or biomass combustion apparatuses,

moreover, in the pellet and / or biomass combustion apparatuses it is not possible to vary the quantity of air as in the gas combustion apparatuses. The amount of air must be constant according to the measured power as it is possible to eliminate the clinker and unburnt residues that block the burner.

Patent EP 1 219 889 A1 claims a combustion apparatus in which the regulation of combustion is carried out by regulating the quantity of oxygen with a fan to regulate the flow of air.

In pellet and / or biomass combustion apparatuses it is not possible to vary the quantity of oxygen through the variation of the quantity of air, because it is necessary to have a combustion with excess air in order not to block the burner with clinkers and unburnt residues. The clinkers and unburnt residues would block the burner reducing the autonomy of the pellet and / or biomass stoves. The aforesaid regulation systems operating for gas combustion apparatuses do not work for pellet and / or biomass combustion apparatuses. In fact, if there is an oxygen sensor in the pellet and / or biomass apparatus, it is placed directly at the flue gas outlet, while in the pellet and / or biomass apparatus the oxygen sensors are placed in settling chambers.

If the oxygen present in the pellet and / or biomass combustion systems were present at the flue gas outlet, the oxygen sensors would be neutralized by the ash and fine dust produced by the pellet and / or biomass combustion systems .

The present invention intends to eliminate the aforementioned drawbacks. The purpose of the present invention is therefore to create a combustion apparatus for stoves and thermo-stoves fueled by pellets and / or biomass that allows the regulation of the various control parameters of the stove / boiler not only a priori, but also during the operation of the stove / boiler. itself so that, if the control parameters set upstream and considered optimal vary during stove / boiler operation, it is possible to supply a greater or lesser quantity of fuel and / or comburent to the stove / boiler depending on the deviation of the parameters detected with respect to the standards set.

A further object of the present invention is to realize a combustion apparatus fed by pellets and / or biomasses which is more efficient than known combustion apparatuses.

The aforesaid objects are achieved by the present invention relating to a combustion apparatus fed with pellets and / or biomass whose fundamental characteristics are in accordance with the teachings of the first claim.

Further characteristics of the combustion apparatus according to the invention are the subject of the dependent claims.

Advantageously, the combustion apparatus according to the invention uses a plurality of sensors, external to the combustion chamber, which allow continuous monitoring of the various control parameters of the stove / boiler by comparing them with pre-set reference values by means of a control feedback and that, according to requirements, the quantity of fuel and / or comburent in the apparatus itself varies.

Equally advantageously, the combustion apparatus according to the invention is consequently more efficient and more respectful of the environment as it is less polluting and allows a considerable reduction in the operating costs of the combustion apparatus itself.

Equally advantageously, the combustion apparatus according to the invention allows to manage the fuel and / or comburent supply by means of an electronic control unit that emits control signals that command mechanical means for conveying combustion and / or comburent. , ie air, in the combustion chamber.

The aforementioned sensors which continuously monitor the stove / boiler control parameters include at least one smoke temperature sensor, at least one depression sensor in the combustion smoke evacuation circuit, at least one temperature sensor of the room to be heated.

These sensors send their signals to an electronic control unit which processes these signals, compares them with the pre-set ones and consequently transmits suitable command signals to the means that regulate the flow of fuel and / or comburent.

According to a preferred embodiment, the aforesaid sensors comprise, in addition to what has been specified above, also at least one lambda probe for measuring the emissions of the combustion waste gases, at least one atmospheric pressure sensor, at least one sensor for measuring the ambient temperature outside the building where the boiler / stove is located, at least one humidity sensor in the room where the heating appliance is installed. The aforesaid purposes and the aforesaid advantages will be better highlighted during the description of a preferred embodiment of the invention, which is given by way of indication but not of limitation, with reference to the attached drawing tables in which:

- fig. 1 shows a block diagram illustrating the operation of the combustion apparatus fed with pellets and / or biomass according to the invention;

- fig. 2 shows a block diagram of an embodiment variant of the diagram of fig. 1;

- fig. 3 shows a schematic view of the combustion apparatus fed with pellets and / or biomass according to the invention.

With reference to fig. 3, the combustion apparatus is indicated as a whole with 1, 20 and comprises a combustion chamber 2 fed by a fuel and a comburent. In accordance with the present invention, the combustion apparatus 1 comprises a feedback combustion control unit 3, to which one or more signals from control sensors external to said combustion chamber are received. At the output, the control unit emits electrical signals to control means for varying the fuel and comburent supply in the combustion chamber 2.

In particular, the control group 3 consists of an electronic control unit managed by a software for processing the incoming data. The input signals are compared with a series of pre-set parameters relating to the temperature of the fumes, the static and dynamic depression, the ambient temperature.

With reference to the embodiment of fig. 1, the combustion apparatus 1 comprises a depression sensor 4 which measures the static and dynamic depression in the combustion smoke evacuation circuit of the stove / boiler and processes a smoke extraction curve 5, obtained on the basis of the input data .

The data obtained at the output from the smoke extraction curve are processed by the control group 3 which, in case of discrepancy with what is pre-set, emits electrical output signals which are sent to a fan (not shown) which regulates the quantity. of combustion agent, that is of the air.

Again with reference to fig. 1, the combustion apparatus 1 also includes a flue gas temperature sensor 6 leaving the combustion chamber 2. The signals of the sensor 6 process a fuel load curve 7, taking into account the flue gas temperature / quantity of fuel ratio fed in the unit of time.

The output data from curve 7 are processed by the control unit 3 which, in case of deviation from the set parameters, emits electrical output signals to regulate the quantity of fuel that is loaded through the activation of actuators of known type (not shown) that modify the supply of the quantity of fuel to be introduced into the boiler.

The combustion apparatus 1 also comprises a room temperature sensor 8, which measures the temperature of the room to be heated and which elaborates a climatic curve 9.

The output data from the climatic curve 9 are processed by the control unit 3, which also in this case emits electrical signals for regulating the quantity of fuel in the stove / boiler via the above electric motors or for regulating the combustion agent, that is, of the air, by means of the above fan. Both types of regulation take place as a function of the temperature difference to be bridged with respect to the pre-set data.

Fig. 2 represents a preferred embodiment of the combustion apparatus according to the invention, now indicated with 20, which differs from that illustrated in fig. 1 due to the fact that, in addition to the depression sensors 4 in the flue gas evacuation circuit, the flue gas temperature sensors 6 and the room temperature sensors 8 to be heated, there are further control sensors.

In fact, in the room to be heated and connected to the control group 3, there is an atmospheric pressure sensor 21, which interacts with the depression sensor 4 described above to elaborate a smoke extraction curve 22.

In the elaboration of the smoke extraction curve 22 and the fuel load curve 23, a humidity sensor 24 also intervenes, which measures the humidity of the environment in which the stove / boiler is inserted, considering the incidence of relative humidity in the combustion process.

The combustion apparatus 20 of fig. 2 also includes an external temperature sensor 25, which measures the temperature of the environment outside the building where the stove / boiler is located and calculates the difference between the detected temperature value and the pre-set one. adjusting the quantity of fuel and / or comburent according to the temperature difference to be filled. Again according to the example of fig. 2, the combustion apparatus 20 finally includes also a lambda probe 27 which measures the emissions of the combustion waste gases, in particular of the NOx and CO, intervening in the elaboration of the fuel load curve 23 and in the elaboration of the climatic curve 26.

Furthermore, the lambda probe 27 activates, if necessary, an electrostatic filter 28 for the abatement of fine dust (the so-called PM10), in such a way as to respect the predetermined emission values. As can be understood from what has been described, the combustion apparatus according to the invention achieves all the intended purposes.

In particular, according to a preferred embodiment of the invention, the combustion apparatus comprises at least one smoke temperature sensor, at least one depression sensor in the combustion smoke evacuation circuit, at least one temperature sensor environment to be heated, at least one lambda probe for measuring the emissions of combustion waste gases, at least one sensor for atmospheric pressure, at least one sensor for measuring the temperature of the environment outside the building where the boiler / stove is located, at least one humidity sensor of the room in which the heating appliance is installed.

Through all these control sensors and through the electronic control unit that carries out a feedback control it is possible to obtain a continuous monitoring of the stove / boiler, obtaining very high yields and reducing costs by about 60% compared to known combustion equipment.

Changes may be made to the combustion apparatus fed with pellets and / or biomass according to the invention which, if they fall within the scope of the following claims, must be considered protected by this patent.

Claims (8)

CLAIMS 1) Pellet and / or biomass combustion apparatus (1; 20) of the type comprising: - a combustion chamber (2) adapted to be fed by a fuel and / or an comburent; - an exhaust circuit with fan for forced smoke extraction connected to said combustion chamber (2); - a plurality of sensors for detecting the operating conditions of said apparatus (1; 20); - a combustion control unit (3), characterized in that said combustion control unit (3) is provided with one or more input ports for signals from said detection sensors connected to said input ports and one or more output ports for command and control signals control for at least means for feeding the fuel-combustive mixture into said combustion chamber (2) and means for extracting the fumes from said combustion chamber (2), said control unit (3) providing feedback commands based on the detected values from said sensors. 2) Apparatus (1; 20) according to claim 1) characterized in that said control unit (3) is connected to means for detecting the percentage of oxygen in the fumes. 3) Apparatus (20) according to claim 1) or 2) characterized in that said sensors for detecting the operating conditions of said apparatus comprise: - at least a first sensor (8) for detecting the internal ambient temperature; - at least a second sensor (25) for detecting the external ambient temperature; - at least a third sensor (6) for detecting the flue gas temperature; - at least a fourth sensor (4) for detecting the depression in the combustion chamber (2); - at least a fifth sensor (21) for detecting the atmospheric pressure. 4) Apparatus (1; 20) according to any one of the preceding claims, characterized by the fact that in said control unit (3) there are programmable means for processing and feedback regulation of said input and output signals. 5) Apparatus (20) according to claim 3) characterized in that said first sensor (8) and second sensor (25) are temperature probes for processing a climatic curve (26). 6) Apparatus (1; 20) according to claim 3) characterized by the fact that said at least a third sensor (6) is a temperature probe for processing a fuel load curve (7; 23). 7) Apparatus (20) according to claim 3) characterized by the fact that said fourth sensor (4) and fifth sensor (21) are depression sensors for processing a smoke extraction curve (22). 8) Apparatus (20) according to claim 2) characterized in that means for detecting the percentage of oxygen in the fumes comprise at least one lambda sensor (27) arranged in the outlet fumes.