Patent Grant
8137098
This application claims priority to Spanish Patent Application No. U200800992, filed May 12, 2008.
The present invention relates to a pilot burner with adapted to multiple or dual household heating appliances that may be supplied with natural gas (NG) or liquefied petroleum gas (LPG), such as stoves or water heaters, preferably non-ventilated.
There are known household heating appliances in the prior art that include pilot burners with oxygen depletion sensors. The level of oxygen in a typical ventilated room is generally around 21%, which allows the combustion of a combustible fluid to take place correctly. Problems arise when the level of oxygen falls below 18%, a situation that may occur in non-ventilated household heating appliances and which leads to poor combustion of the combustible fluid, carbon monoxide thus being generated and causing a corresponding danger to the user. To prevent the problem, pilot burners include oxygen depletion sensors that block the passage of combustible fluid to the burners when the level of oxygen detected falls below 18%.
Known single gas pilot burners with oxygen depletion sensors generally comprise a safety thermocouple that generates an electrical current when heated by a pilot flame, the electrical current acting on a control valve to keep it open and, therefore, the passage of combustible fluid to the burners of a heating appliance, a spark generator that causes the ignition of the combustible fluid, an injector that comprises a mixing chamber where air is mixed with the combustible fluid, and a nozzle through which the injector supplies the pilot flame that heats the safety thermocouple, the safety thermocouple, the spark generator and the injector typically being fixed on a support to the interior of the heating appliance.
There are also known dual gas heating appliances in the prior art (i.e., heating appliances that may be supplied by two different combustible fluids), the combustible fluids preferably being natural and propane gas, and which include a pilot burner with oxygen depletion sensor for each combustible fluid, with the result that two each of most of the necessary components are required
United States patent application published as US2007/0266765 A1 discloses a dual heating appliance that incorporates a single pilot burner for both combustible fluids, the pilot burner comprising a safety thermocouple, a spark generator, a first injector that is supplied with a first combustible fluid, and a second injector that is supplied with a second combustible fluid, the safety thermocouple, the spark generator and the first and second injectors being supported on a single support. The first injector and the second injector are disposed at an angle in relation to the safety thermocouple and facing each other, with the result that a first pilot flame supplied by the first injector heats one face of the safety thermocouple, while a second pilot flame supplied by the second injector heats the other face of the safety thermocouple.
The object of the invention is to provide a pilot burner adapted to multiple or dual household heating appliances, such as stoves and water heaters, that may be supplied with multiple combustible fluids such as a first combustible fluid or with a second combustible fluid as described herein and recited in the appended claims.
In one embodiment, the pilot burner comprises a safety thermocouple, an igniter (e.g., spark generator), and an injector that includes a nozzle through which it supplies a pilot flame, the pilot flame heating the thermocouple.
In an embodiment, the injector comprises a combustion body that is connected to a first supply pipe for the first combustible fluid, to a second supply pipe for the second combustible fluid, and to the nozzle. A compact pilot burner is thus obtained, which, with a single injector, a single igniter (e.g., spark generator) and a single thermocouple, may be supplied by two different types of combustible fluid according to requirements, thereby avoiding the need to use a pilot burner for each type of combustible fluid. This thus reduces the space required in the interior of the heating appliance for the pilot burner, optimises the dimensions of the pilot burner, and reduces costs as fewer elements are used.
These and other advantages and characteristics of the invention will be made evident in the light of the drawings and the detailed description thereof.
With reference to
In one embodiment, the injector 5, shown in detail in
The pilot burner 1 comprises an L-shaped support 8, which may be fixed in the interior of the heating appliance, and which includes a first segment 8a with a substantially U-shaped section, upon which the igniter 3 and the thermocouple 2 are fixed by means of a bracket 8c, the bracket 8c being fixed to the first segment 8a by means of a screw 30, and a second segment 8b with a substantially U-shaped section, onto which the injector 5 is fixed. The second segment 8b includes, on one of the branches of the U, a hole 32 through which the injector 5 passes, the injector 5 being fixed to the branch by means of a nut 31, and, on the other branch, a wide hole 33 into which the combustion pipe 19 of the injector 5 is tightly fitted through an external perimeter groove 29 included in the combustion pipe 19, thereby preventing the injector 5 from rotating in relation to the support 8.
In one embodiment, the thermocouple 2 and the igniter 3 are disposed parallel to each other, while the injector 5 is disposed substantially orthogonally to the thermocouple 2 and the igniter 3.
In addition, the combustion body 7, shown in detail in
The first combustion pipe 10 is preferably disposed concentrically and continuously to the first mixing chamber 11, the central or axial axis of the first combustion pipe 10 forming a first angle A in relation to the central or axial axis of the connection chamber 16, and the second combustion pipe 12 is preferably disposed concentrically and continuously to the second mixing chamber 13, the central or axial axis of the second combustion pipe 12 forming a second angle B in relation to the central or axial axis of the connection chamber 16. In the embodiment shown in the figures, the first angle A and the second angle B are equal and of a maximum value of 10°, thereby minimising the load loss of the combustible fluid as it passes through the connection chamber 16.
Furthermore, the first connector 20 and the second connector 21, shown in detail in
The first mixing chamber 11 includes, on a side wall, a first hole 17 or first holes 17 that are preferably disposed diametrically opposite to each other and through which air enters, thus causing in the first mixing chamber 11 a first mixing of air/combustible fluid (e.g., air/natural gas), while the second mixing chamber 13 includes, on a side wall, a second hole 18 or second holes 18 that are preferably disposed diametrically opposite to each other and through which air enters, thus causing in the second mixing chamber 11 a second mixing of air/combustible fluid (e.g., air/propane), the diameters of the first hole 17 and the second hole 18 being defined, as well as the first calibrated hole 24 and the second calibrated hole 26, in accordance with the type of combustible fluid, natural gas or propane, that passes through the first mixing chamber 11 and the second mixing chamber 12 respectively.
In the embodiment shown in
When the pilot burner 1 is operating normally (i.e., when the ambient oxygen levels are above 20%), the combustion of the corresponding combustible fluid takes place correctly, and the pilot flame 4 is of such a length that it heats the safety thermocouple 2, with the result that the thermocouple 2 generates a current that powers the control valve. The current generating a magnetic field within the control valve to keep the control valve open and, therefore, the passage of combustible fluid to the injector 5 of the pilot burner 1, and to injectors, not shown in the figures, in the main heaters of the heating appliance.
In the event that the levels of ambient oxygen are below 20%, the combustion of the corresponding combustible fluid does not take place correctly. As there is not a sufficient supply of oxygen to maintain the stoichiometric proportion of the mixture to ensure correct combustion, the pilot flame 4 begins to burn more quickly in an effort to absorb more air, the flame shortening before eventually going out. In such a situation the thermocouple 2 cools down and does not generate the necessary current to power the control valve to keep it open, as a result of which the control valve blocks the passage of combustible fluid to the pilot burner 1 and to the main burners. The first air intake hole or holes 17 and the second air intake hole or holes 18 are of such a size that when the level of oxygen in the enclosure falls below the stipulated safety limits, preferably at or below 20%, the burner switches off regardless of the type of gas being used.
Although this invention has been disclosed in the context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the present invention extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the invention and obvious modifications and equivalents thereof. Thus, it is intended that the scope of the present invention herein disclosed should not be limited by the particular disclosed embodiments described above, but should be determined only by a fair reading of the claims that follow.
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