IT202100019742A1 - PYROLYTIC HEATER WITH IMPROVED COMBUSTION CHAMBER - Google Patents

Description

DESCRIPTION

The object of the present invention is a pyrolytic combustion heater equipped with an improved combustion chamber which reduces the generation of fumes. The heater in question? usable both for cooking equipment, such as plate barbecues, and for heating equipment, such as braziers. The heater in question? therefore suitable for barbecues, ovens, braziers, stoves, mushrooms and other similar equipment powered by wood chips, pellets, wood or other biomass.

Known heaters comprise an open combustion chamber in which a flame is generated, and above which a centrally perforated plate is arranged and intended for the diffusion of heat or for cooking food. In these known heaters, the flame is produced in the center of the combustion chamber and tends to escape immediately from the central opening of the plate, which is therefore only partially heated in an uneven way and over a rather long time. Furthermore, known heaters often lead to non-optimal combustion which generates many fumes.

Purpose of the present invention? that of realizing a heater equipped with a combustion chamber in which the pyrolysis is improved by avoiding the formation of fumes.

That purpose? achieved by a heater according to claim 1. The dependent claims describe preferred embodiments of the invention.

The characteristics and advantages of the heater in accordance with the present invention will be evident from the following description, given by way of non-limiting example in accordance with the attached figures, in which:

figure 1 shows a sectional view of a heater in accordance with the present invention, in an embodiment;

figure 2 shows a sectional view of a heater in accordance with the present invention, in a further embodiment;

figure 3 shows a sectional view of a heater in accordance with the present invention, in yet another embodiment;

- figure 4 shows a side view of the heater of figure 1, supported and equipped with a support. The heater 1 in accordance with the present invention ? usable as cooking equipment, for example as a griddle barbecue, or as heating equipment, for example as a brazier. The heater in question? fed with a C fuel, e.g. wood chips, pellets, wood or other biomass such as dry agricultural waste, dry food waste.

The heater 1 comprises a main portion 110 defined by an outer wall 144 and an outer bottom 141. Preferably, the main portion 110 is? cylindrical, but can? also assume other forms, such as cubic, parallelepiped, polygonal. The main portion 110 houses the combustion chamber 130 in which the pyrolysis takes place. The combustion chamber 130 ? defined between a side wall 134, a bottom 131 and a plug 132. The combustion chamber 130 is then closed at the top by the plug 132 which prevents the escape of the gases generated during the pyrolysis. The combustion chamber 130 has a volume which determines the capacity? of the heater 1 and therefore the duration of combustion and heat production of the same. The combustion chamber 130 ? suitable for containing the fuel C which, thanks to pyrolysis, produces the syngas, indicated with G in the figures.

The combustion chamber 130 ? fluidically connected to a ventilation opening 30 which allows the passage of air inside the chamber itself. The air coming from the ventilation opening 30 ensures correct combustion of the fuel C in order to obtain its pyrolysis and the consequent production of syngas.

The ventilation opening 30 ? suitable for the entry of air through a natural ventilation system, or through a forced ventilation system 301, such as a fan. The 301 forced ventilation system? capable of varying the flow of air inside the combustion chamber 130 in a predetermined manner in order to regulate the progress of the pyrolysis as described above. The 301 forced ventilation system can? be a radial or axial system according to construction requirements. In an embodiment, shown in figure 1, the forced ventilation system 301 is directly connected to the ventilation opening 30. In the embodiment of figures 2 and 3, the forced ventilation system 301 is not? connected to the ventilation opening 30, but ? placed at a certain distance below it, so as not to overheat. In the embodiment of figure 4, the forced ventilation system 301 is disposed at a certain distance below the ventilation opening 30 and ? supported by a support 3, described more? after you. Returning to figure 1, the fund 131 ? drilled or grid allowing cos? the uniform entry of the air coming from the ventilation opening 30. Advantageously, the air coming from the ventilation opening 30 is heated before being introduced into the combustion chamber 130, allowing a better combustion of the fuel C, a clear reduction of the fumes and a better production of syngas.

Preferably, the heater 1 comprises an air inlet duct 170, which connects the ventilation opening 30 with the combustion chamber 130, which extends at least partially inside the combustion chamber 130 so that the air is heated from the combustion of fuel C.

Preferably, the air intake duct 170 comprises a delivery portion 174, cylindrical and centrally arranged, and a return portion 175, toroidal and arranged around the delivery portion 174. As shown in figure 1, the fresh air flows towards the it rises in the delivery portion 174 as it heats up, and descends in the return portion 175 by now hot enough to enter the combustion chamber 130 through the bottom 131.

Around the combustion chamber 130 ? a peripheral chamber 140 is arranged, toroidal, coaxial to the combustion chamber 130. The peripheral chamber 140 is a gap defined between the outer wall 144 and the combustion chamber 130. The peripheral chamber 140 is closed at the bottom by the external bottom 141 which helps to define its volume.

In the embodiment of figure 1, the ventilation opening 30 also allows the passage of air inside the peripheral chamber 140. In fact, the hot air coming from the return portion 175 enters both the combustion chamber 130 through the bottom 131 and into the peripheral chamber 140 through at least one connecting passage 136.

The heater 1 therefore comprises an air chamber 190 of hot air which feeds both the combustion chamber 130 and the peripheral chamber 140. Preferably, the air chamber 190 is arranged below the bottom 131 of the combustion chamber.

In the embodiment of figure 2, the external bottom 141 ? connected to a secondary ventilation system 40, preferably a forced ventilation system such as for example a fan, which allows the passage of further air inside the peripheral chamber 140.

The heater 1 also comprises an upper portion 120 equipped with a plate 2 which can be used as a cooking surface for food or as a heat diffuser. Plate 2 ? equipped with a central opening 21 and an external perimeter 22.

In the embodiment of figures 1 and 2, the upper portion 120 ? a continuation of the main portion 110.

In the embodiment of figure 3, the upper portion 120 has an upwardly flared section, ie a truncated cone, ie it has an upper perimeter greater than a lower perimeter. In this example, the main portion 110 ? more small, i.e. it has a smaller volume than the upper portion 120.

As can be seen in figures 1-3, the combustion chamber ? provided at the top with at least one gas outlet 136 for the gases G generated during the pyrolysis. Indeed, the combustion chamber 130 ? connected to an internal gap 180 arranged in the upper portion 120. Therefore, the gases G generated during pyrolysis enter the internal gap 180 of the upper portion 120. The peripheral chamber 140, on the other hand, is connected to a peripheral gap 160 of the upper portion 120. Therefore, the hot air stream A enters the peripheral gap 160 of the upper portion 120. Therefore, the combustion chamber 130 and the peripheral chamber 140 are separated from each other on the other.

The upper portion 120 comprises a central chamber 150 defined between a side wall 154, a bottom represented by the plug 132 and a lid represented by the plate 2. Since the plate 2 has a central hole 21, the central chamber 150? open, and allows manual loading of the solid fuel into the combustion chamber 130 through the cap 132.

Around the central chamber 150, separated by the side wall 154, ? arranged the internal cavity 180, toroidal and coaxial. The internal cavity 180 ? connected below to the combustion chamber 130 via at least one gas outlet 136.

Around the internal cavity 180 in which the pyrolysis gases flow, separated by an intermediate wall 151,? the peripheral gap 160 is arranged, toroidal and coaxial, defined between an upper external wall 152 and the intermediate wall 151. The peripheral gap 160 is arranged. connected to the peripheral chamber 140 of the main portion 110.

Above, both the peripheral gap 160 in which the hot air stream A flows and the internal gap 180 in which the pyrolysis gases G flow, flow below the plate 2. Preferably, the peripheral gap 160 and the The internal cavity 180 flows below the external perimeter 22 of the plate 2. Therefore, the gases produced by the pyrolysis of the solid fuel meet hot air below the external perimeter 22 of the plate 2, where their combustion takes place, generating the characteristic flame typical of pyrolytic burners. The flame, generated along the external perimeter 22 of the plate 2 then spreads underneath the whole plate until it comes out of the central opening 21. In this way the plate 2 is heated uniformly and in a few minutes.

In the example of figure 4, the heater 1 ? supported by a support 3. The support 3 comprises a pedestal base 31 for resting on the ground and a brazier base 33 on which the heater 1 rests.

Preferably, heater 1 is made of iron-based alloys, such as steel or cast iron, or titanium.

Preferably, plate 2 ? in metal (for example steel) treated with hardening in order to flex upwards, or become convex, when it is heated thus allowing? operator to remove the food and oil residues by pushing them towards the external perimeter 22 equipped with a special drainage channel 221. This solution prevents the cooking residues from falling into the central chamber 150 of the upper portion 120, forming unwanted fumes.

The operation of the heater 1 according to the present invention can be described in the following way.

A fuel C is introduced into the combustion chamber 130 so as to reach the predetermined filling level which varies on the basis of the volume of the combustion chamber itself.

The fuel load C in the combustion chamber 130 can be performed manually or automatically through an automatic loading system, such as a screw. The fuel C inside the combustion chamber 130 can? be ignited by means of a starting auxiliary fuel, such as for example paraffin, ethanol or flammable hydrocarbons, or by means of a starter electrode, for example an electric resistance.

Once lit, the fuel generates a quantity? of heat which allows to heat the combustion chamber 130, bringing the primary fuel to the optimal pre-established temperature so that? the pyrolytic process is triggered. The combustion of the fuel C generates a flammable gas in the combustion chamber 130. The pyrolysis gas G rises upwards until it meets the hot air flow A coming from the peripheral chamber 140 and, following ignition, burns and forms a flame F. Preferably, the cap 132 of the combustion chamber 130 is equipped with a hole from which a flame emerges to trigger the combustion of the hot air A and the pyrolysis gas G below the plate 2.

Innovatively, in the heater 1 according to the present invention, the combustion in the combustion chamber is fed with hot air, thus improving? pyrolysis and reducing the formation of fumes.

? it is clear that a technician in the sector could make modifications to the product described above, all contained within the scope of protection as defined by the following claims.

Claims (10)

1. Pyrolytic heater (1) equipped with a main portion (110) comprising: - a combustion chamber (130), in which the pyrolysis of a fuel (C) which generates pyrolysis gas takes place, said combustion chamber (130) being connected to a ventilation opening (30) which supplies inlet air to the room itself; - a peripheral chamber (140), arranged around the combustion chamber (130), in which flows a flow of air intended to meet the pyrolysis gases to generate a heating flame (F); characterized in that the air entering the combustion chamber (130) is heated air. The pyrolytic heater (1) according to claim 1, wherein the combustion chamber (130) is connected to the ventilation opening (30) via an air intake duct (170) which extends at least partially inside the combustion chamber (130). The pyrolytic heater (1) according to claim 2, wherein the air inlet duct (170) comprises: - a delivery portion (174), cylindrical and central; - a return portion (175), toroidal and arranged around the delivery portion (174). 4. Pyrolytic heater (1) according to any one of the preceding claims, wherein also the peripheral chamber (140) is? connected to the ventilation opening (30) and also the air entering the peripheral chamber (140) ? heated air. 5. Pyrolytic heater (1) according to claim 4, wherein the air entering the peripheral chamber (140) comes from the air inlet duct (170). 6. Pyrolytic heater (1) according to any of the preceding claims, comprising an air chamber (190) of hot air which feeds both the combustion chamber (130) and the peripheral chamber (140). A pyrolytic heater (1) according to any one of the preceding claims, comprising an upper portion (120), connected to the back of the main portion (110), and comprising: - an upper plate (2), having an outer perimeter (22) and a central opening (21); - an internal toroidal interspace (180) connected below to the combustion chamber (130), in which the pyrolysis gases from the combustion chamber (130) flow; - a peripheral cavity (160), toroidal, arranged around the internal cavity (180), connected below to the peripheral chamber (140), in which the hot air from the peripheral chamber (140) flows; - wherein the peripheral gap (160) and the internal gap (180) flow underneath the plate (2), at its outer perimeter (22). 8. Pyrolytic heater (1) according to claim 7, wherein the plate (2) is metal treated with hardening so that it bends and becomes convex when heated. 9. Pyrolytic heater (1) according to claim 7 or 8, wherein the plate (2) is equipped, at the external perimeter (22), with a drainage channel (221) for the collection of cooking residues. 10. Pyrolytic heater (1) according to any one of the preceding claims, supported by a support (3), and in which below the ventilation opening (30) ? arranged a forced ventilation system (301) supported by the support (3).