BR202020016132U2 - CONSTRUCTION ARRANGEMENT INTRODUCED IN SOLID FUEL BIOMASS STOVE (PELLET) - Google Patents

Abstract

constructive arrangement introduced in a solid fuel biomass stove (pellet) the utility model refers to a constructive arrangement in a solid biomass fuel stove (pellet), located in the technological sector of stoves or domestic solid fuel stoves, specifically the constructive dispositions for circulation of combustion air inside or around stoves, aiming to optimize and control the exchange of heat and the thermal use of gases in the stove, both for heating the environment and for cooking food. there are several models of stoves that use solid fuel, however, they do not present a good use of the heat generated by the burner, causing low thermal efficiency; as well as, they do not have a safety device against overheating, which can cause food burning or excessive temperature in the environment. for that, it comprises a cabinet (1) with controller (6), glass ceramic cooking table (7), oven (3) and firing chamber (5) with burner (9) and connected to the feeder (11); being that it has an air inlet (13) next to the microfan (14) with an inlet (15) with piping (16) to the burner (9) in the chamber (5), which has a passage (17) to the table (7 ) provided with passage (18) to the oven (3) provided with side passage (19), deflector (20) and followed by an exhaust fan (21) with opening (22) for the chimney (not shown); being that it is still equipped with a safety device against overheating composed of a temperature sensor (23) in the oven (3), and a temperature sensor (24) next to the burner (9), interconnected to a printed circuit board ( 25) of the controller (6).

Description

CONSTRUCTION ARRANGEMENT INTRODUCED IN SOLID FUEL BIOMASS STOVE (PELLET) INTRODUCTION

[001] This utility model refers to an innovative constructive arrangement introduced in a solid biomass fuel stove (pellet) located in the technological sector of solid fuel stoves or domestic stoves, more precisely, constructive arrangements with air circulation of combustion or combustion gases inside or around stoves, with the objective of optimizing and controlling the exchange of heat, and the thermal use of the heat of the gases inside and outside the stove, both for cooking food and for the heating of the environment; as well as the control of the temperature generated through a safety device that cuts off the supply of pellets to the burner when there is an excess of heat, by means of monitoring through a set of temperature sensors.

STATUS OF THE TECHNIQUE

[002] It is known from the state of the art that there are several models of stoves that use solid fuel, mainly pellets, however, one of the characteristics inherent to the equipment of the current state of the art refers to the fact that the exit of gases to the chimney It takes place at the top, generating a low pressure that increases the flow of hot air excessively through the interior of the stove, not providing the total transfer of heat generated by the burner, which ends up exiting through the chimney, causing low thermal utilization. . This problem becomes worse when a centrifugal fan is adopted, used to pull the air to the outlet through the stove chimney, causing the generated heat to not be used to the fullest.

[003] Still, in existing stove models in the state of the art, the hot air path first reaches the oven and then reaches the table at the top, causing the oven to receive gases with temperature peaks, what happens when more firewood or pellets are placed in the combustion system, and such temperature peaks end up abruptly altering the food processing conditions in the oven, which can even lead to the food burning.

[004] Also characteristic of the currently existing stove models is that, because the chimney outlet is positioned at the top, it ends up interfering with the table surface, making it difficult to use a tempered glass table, in order to allow the cooking of food directly on the surface.

[005] Likewise, in the models of stoves currently existing, the positioning of the chimney outlet at the top causes the flow of hot air to occur directly from the bottom to the top, without going through paths that can increase the heat exchange, the that, added to the fact that, in many stove models, there is a fan for the air outlet, it ends up causing a low pressure on the internal part of the equipment, not favoring the exchange of heat, resulting in less thermal use.

[006] Finally, in the currently existing stove models, if the desired temperature is exceeded, there is no device to control the temperature by controlling the pellet feed, which will continue to be done next to the burner, producing even more heat, which can cause the stove to overheat and the food to burn, or the temperature in the room to be too high.

[007] From the current state of the art, one can cite patent document PI0303647-2, filed on 10/14/2003 and entitled "ECOLOGICAL, EFFICIENT AND SMOKE-FREE FIREWOOD STOVE", which describes a stove consisting of a chamber 'L'-shaped combustion chamber (A) immersed in a thermally insulating environment (C), a cast iron sheet (D), a chimney (F), all structured by angles (H) and galvanized or anti- corrosive (I). Additionally, this stove can have an oven (E) and a coil system (G) for water heating coupled around the combustion chamber, or on the plate, or even on the external base of the chimney.

[008] The patent document MU8900584-8, filed on 04/08/2009 and entitled "DISPOSITION IN WOODEN STOVE", aims at a wood stove comprising the furnace (7) facing the front wall (2) , consisting of two contiguous and orthogonal chambers, one anterior and horizontal (71) for combustion of firewood and a posterior and vertical (72) for conducting the gases to the top plate (1). The combustion chamber (71) has a base (73) in the form of a split chute which is covered by a semicircular roof (74). The rear chamber (72) has a long rear wall (75) and a short front wall (76), both semicircular, forming a vertical duct. Preferably, the split base (73), the roof (74) and the front wall (76) are molded of ceramic or refractory material, while the rear wall (75) is of cast iron. Around the upper mouth of the duct (72) deflector plates (8) of the hot gases on the top plate (1) of the stove are arranged. The mouth of the firebox (7) has a frame (9) for connection to the front plate (2) of the stove and which receives a tilting door (91). An ashtray drawer (92) slides into the bottom of the firebox base (73). A grate (93) slides into grooves in the base of the furnace (73) and is positioned above the drawer (92). A constructive option of the wood stove presents an oven (10) orthogonal to the furnace (7). The side wall (12) of the furnace is fixed to the central portion of the rear wall (75) of the furnace. Still optionally, the wood stove can have a coil (13) in the form of a "U" bent tube that starts at the rear wall (4) of the stove, goes around the mouth of the upper chamber of the firebox (72) and returns to the rear wall. (4).

[009] Patent document BR 10 2015 025786 4, deposited on 10/09/2015 and entitled "OVEN FOR WOODEN STOVE", describes an oven whose main part (1) is formed by the 4 walls containing the hot air channels (6), which increase the heat transmission area and thus increase heating speed and fuel economy. The plate corresponding to the back wall (2) is located opposite the access door (3). The input and output of the channels are respectively numbered (4) and (5).

[010] Patent document MU 6501878-8, filed on 11/20/1985 and entitled "CONSTRUCTIVE DEVICE IN STOVE THAT USES SAWSTUD OR TICKS AS FUEL", which describes a constructive arrangement in stove that uses sawdust or kindling as fuel , consisting of a body (1), having in its upper part a plate (2) and respective mouths (3) with lids (4), while in its inner part there is a partition (5), configuring two compartments, one for the oven (8) and another for the heating chamber (9), the latter formed by a plate (10) and a vent, while the other is formed by a box (14) with a door (15) and a vent (16), as well as said oven (8) communicates with chimney (9). It can be seen, in the sectional views of the compartment (1), that the heated air leaves the burner and first passes through the upper part, next to the plate (2), and then follows and passes through the oven (8), around the compartment. (14).

[011] Likewise, the concept present in the object of the patent MU 6501878-8 requires a procedure for its operation, which is the need to use a wooden cylinder (23) to promote the generation of a tunnel for the ventilation in the middle of the sawdust (5), which must be tamped down sufficiently to maintain the conformation.

[012] This procedure does not prevent the situation in which, as the gas stream is ascending, and moves directly to the upper plate, when there is a sudden increase in combustion, the gases at high temperature immediately increase the temperature of the plate. (2), and, consequently, of the food being processed, with the risk of burning it, requiring the user to be attentively taking care of the entire food preparation process.

UTILITY MODEL SOLUTION

[013] The object of the present utility model is an innovative constructive arrangement introduced in a solid biomass fuel stove (pellet) that provides for the insufflation of air through the lower part of the stove, promoting the generation of an air flow, from the bottom, towards the top, where the cooking table is positioned.

[014] Such a configuration has two innovative technical characteristics that optimize the operation of the equipment: a) As for the improvement of the internal operation, the air supply from the bottom up, followed later, from top to bottom, doubles the path of the combustion gases , which enhances the transfer of heat to the cooking table of the stove so that it becomes warm enough to optimize food preparation; as well as, following the flow of hot air in a downward movement through the internal side of the stove, around the oven, already at a more attenuated and homogeneous temperature, without temperature peaks, in order to maintain a more adequate control of the roasting process in the oven. . b) As for the improvement of external functioning for the environment, the fact that the intake air enters the stove through a micro-fan, at the bottom, causes the forced capture of cold air from the environment, which passes through the ascending circulation through the interior of the stove to the cooking table, which also serves as a space heating surface, and, descending through the side of the oven, exits through the chimney located at the bottom, that is, it releases heat in the lower region of the environment, normally with a lower temperature, allowing the maximum use of heat for the environment, thus achieving better performance.

[015] The cooking table receiving the initial flow of hot air will act as a thermal buffer, preventing temperature peaks from reaching the oven uncontrolled, which could cause the food to burn during the baking process; and, at the same time, the table stores heat for moments when the temperature of the hot air generated by the furnace decreases, when it helps to maintain the temperature of the hot air to be transferred to the oven, which guarantees greater homogeneity and control of the processing. of food.

[016] As already explained, the cooking table receiving the initial flow of hot air also promotes the heating of the environment more effectively, given that its surface will have the highest temperature generated by the burner, and, with the largest contact area with the ambient air, providing greater heat transfer, optimizing the performance of the equipment as a space heater.

[017] The pellet tank positioned next to the stove cabinet promotes the maintenance of low humidity or drying of solid fuel, in order to guarantee its optimized combustion next to the burner; as well as, being equipped with a hopper, it promotes that all the solid fuel (pellet) that is stored is used in the process.

[018] The equipment also has an electronic safety device against overheating, through sensors next to the oven and the burner, which are interconnected to the controller that cuts off the pellet feed to the burner to reduce burning, reducing the temperature on the stove, which avoids the risk of burning food; as well as excessive and unnecessary consumption of solid biomass fuel.

ADVANTAGES OF THE UTILITY MODEL

[019] The new constructive arrangement introduced in a solid biomass fuel stove (pellet), proposed by the present utility model, results in the following advantages in relation to the state of the art: it guarantees the flow of hotter air generated by the stove to promote the space heating; promotes the cooking table to act as a thermal buffer, preventing temperature peaks from reaching the oven and the risk of burning the food inside, and, at the same time, it stores heat for moments when the temperature of the hot air generated by the burner it decreases, when it acts as a hot air temperature maintainer, homogenizing the temperature of the air flow to be transferred to the oven; optimizes the thermal efficiency of the equipment, since it takes advantage of the temperature peaks in the upper part, which is intended for cooking food, and for heating the environment; has the pellet tank positioned next to the stove cabinet, which promotes the maintenance of low humidity or drying of solid fuel, in order to guarantee its optimized combustion next to the burner; as well as, it presents the reservoir equipped with a hopper, allowing that all the solid fuel (pellet) that is stored is used in the process; It features an electronic overheat safety device, which avoids the risk of food burning and excessive consumption of solid biomass fuel.

UTILITY MODEL DESCRIPTION

[020] The innovative constructive arrangement introduced in a solid biomass fuel stove (pellet) of this utility model is now described in detail based on the attached drawings, listed below:
Figure 1 - a perspective view of the constructive arrangement in an idealized pellet stove;
Figure 2 - a left side view referring to figure 01;
Figure 3 - a front view referring to figure 01;
Figure 4 - a right side view referring to figure 01;
Figure 5 - a rear view referring to figure 01;
Figure 6 - a rear view referring to figure 05, in visualization where the set of internal components can be verified;
Figure 7 - a perspective view referring to figure 05, also with visualization for the identification of internal components;
Figure 8 - a schematic view of the electrical circuit diagram of the electronic overheat safety device;
Figure 9 - a front view, in cross section, where the path of the combustion gases through the interior of the equipment equipped with the idealized constructive arrangement is visualized; and,
Figure 10 - a rear view, in cross section, where the path of the combustion gases through the interior of the equipment equipped with the idealized constructive arrangement is visualized.

[021] Figures 1 to 10 illustrate the constructive arrangement introduced in an idealized biomass solid fuel stove (pellet),0020 which comprises a cabinet (1) equipped, on the front, with a door (2) for access to the oven (3), and, a door (4), of access to the firing chamber (5), together with the controller (6); in the upper part, it is equipped with a ceramic glass cooking table (7); and, internally, of the oven (3) and the firing chamber (5), which is equipped with a cooling micro-fan (8) and provided with a burner (9), with cartridge resistance (10), and is interconnected to the feeder with electric motor (11) and pellet tank with hopper (12) in the rear region of the cabinet (1) where, at the bottom, an air inlet (13) is positioned next to the intake microfan (14), the which is followed by an air intake (15) continued by the pipe (16) that culminates in the burner (9), next to the burning chamber (5), which has a direct passage (17) for the flow of combustion gases , on the rise, to the glass ceramic cooking table (7), where there is a second passage (18) for the said gases to follow to the oven (3), which has a lateral passage (19), said to be the passage of the combustion gases, which, by the action of the deflector (20), pass through the lower part of the oven (3) and are sucked by the exhaust fan (21) located in the lower part of the oven. cabinet (1), where there is an opening (22), called the chimney coupling (not shown).

[022] Figures 5, 6 and 7 show the path of entry of cold air from the environment and exit of gases to the chimney (not illustrated) which begins with the air inlet (13) to the intake microfan (14), which is followed by the air intake (15), continuing through the pipe (16), which culminates in the burner (9) next to the firing chamber (5).

[023] Figure 8 shows the electrical circuit diagram of the electronic safety device against overheating, through the control of the feeding of pellets to the burner (9) through the existence of a temperature sensor (23) in the oven (3), and , a temperature sensor (24) next to the burner (9), which are connected to a printed circuit board (25) of the controller (6) where, if the temperature programmed by the user is reached, the feeder (11) ) will turn off automatically, thus, no longer feeding the burner (9), which results in the reduction of the burn and lowers the temperature on the stove or heater, avoiding the risk of food burning, or, excess heat in the environment and unnecessary pellet consumption.

[024] Figure 9 shows a front perspective view, in cross-section, where the cabinet (1) with a ceramic glass cooking table (7) can be seen, inside which the path that the flow of combustion gases travel inside the stove, with the burning chamber (5) equipped with the burner (9) with piping (16), together with the cooling microfan (8); in addition to the path for the rising gases (17) that leads to the cooking table (7) and the oven (3), which has a side passage for the path of the gases (15) being sucked by the extractor (20) that the leads to the opening (21), called the chimney coupling (not shown).

[025] Figure 10 shows a rear view, in cross-section, showing the cabinet (1) equipped with a ceramic glass cooking table (7), inside which, the path that the flow of gases from the combustion runs inside the stove, with the burning chamber (5) equipped with the burner (9) with piping (16), together with the cooling microfan (8); in addition to the path for the rising gases (17) that leads them to the cooking table (7), and, a second passage (18) for said gases to follow to the oven (3), which has a side passage (19). ), called the passage of combustion gases, which, by the action of the deflector (20), pass through the interior of the oven (3) and are sucked by the exhaust fan (21) located in the lower part of the cabinet (1), to the outlet through the opening (21), called the chimney coupling (not shown).

Claims (1)

"CONSTRUCTIVE ARRANGEMENT INTRODUCED IN SOLID FUEL STOVE ON BIOMASS (PELLET)" comprises a cabinet (1) equipped, on the front, with a door (2) for access to the oven (3), a door (4) for access to the firing chamber (5), in addition to the controller (6); and, in the upper part, it has a cooking table (7), characterized by having the cooking table (7) in ceramic glass and, internally, the firing chamber (5) equipped with a cooling micro fan (8) and equipped with a burner (9), with cartridge resistance (10), and is connected to the feeder (11) with a pellet tank with hopper (12) in the rear region of the cabinet (1), where, at the bottom, it is positioned an air inlet (13), next to the inlet microfan (14), which is followed by an air intake (15) continued by the pipe (16) that culminates in the burner (9), next to the firing chamber (5) ), which has a direct passage (17) to the cooking table (7), where there is a second passage (18) to the oven (3), which has a side passage (19) to the deflector (20) , just below and in communication with the oven (3); being that, in the lower part of the cabinet (1), there is an exhaust fan (21) connected to an opening (22), said for coupling the chimney (not shown); being that it is also equipped with an electronic safety device against overheating, through the existence of a temperature sensor (23) in the oven (3), and a temperature sensor (24) next to the burner (9), which are interconnected to a printed circuit board (25) of the controller (6).

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