Patent Grant
11441772
The present disclosure relates to forced-draft pre-mix burner devices, for example in space heaters.
The following U.S. Patents are incorporated herein by reference:
U.S. Pat. No. 5,931,660 discloses a gas premix burner in which gas and air are mixed in a suction region of an impeller to form a combustion mixture. The impeller is associated with a blower housing and an electronic control circuit board, all of which are arranged upstream in a blower chamber having at least one flame separating wall. The arrangement prevents the gas and the combustion mixture from reaching the motor landings or the printed circuit board.
U.S. Pat. No. 7,223,094 discloses a blower for combustion air in a wall/floor furnace that includes a blower housing, and blower wheel, with an air inlet and an air outlet, and with a fuel feeder line for fuel, wherein a mass current sensor for determining the air mass current is located on the air inlet, which is functionally connected with a data processing device and sends signals to the data processing device for calculation of a ratio of combustion medium to combustion air in dependence on a desired heating capacity.
U.S. Pat. No. 9,046,108 discloses a centrifugal blower in a cooling system of an electronic device having asymmetrical blade spacing. The asymmetrical blade spacing is determined according to a set of desired acoustic artifacts that are favorable and balance that is similar to that found with equal fan blade spacing. In one embodiment, the fan impeller can include thirty one fan blades.
This Summary is provided to introduce a selection of concepts that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
A forced-draft pre-mix burner device has a housing that conveys air from an upstream cool air inlet to a downstream warm air outlet. A heat exchanger warms the air prior to discharge via the warm air outlet. A gas burner burns an air-gas mixture to thereby warm the heat exchanger. A fan mixes the air-gas mixture and forces the air-gas mixture into the gas burner. The fan has a plurality of blades with sinusoidal-modulated blade spacing. The fan further has an end cap having an end wall that faces the plurality of blades, an air-gas mixture inlet through which the air-gas mixture is conveyed to the plurality of blades, and an air-gas mixture outlet through which the air-gas mixture is conveyed to the gas burner. The air-gas mixture inlet is connected to the air-gas mixture outlet via a channel formed in the end wall.
The present disclosure is described with reference to the following Figures. The same numbers are used throughout the Figures to reference like features and like components. Unless otherwise specifically noted, articles depicted in the drawings are not necessarily drawn to scale.
It should be understood at the outset that, although exemplary embodiments are illustrated in the figures and described below, the principles of the present disclosure may be implemented using any number of techniques, whether currently known or not. The present disclosure should in no way be limited to the exemplary implementations and techniques illustrated in the drawings and described below.
The present disclosure relates to forced-draft premix gas burners in which air and a combustible gas, such as liquid propane, are fully mixed by a fan and then delivered to a burner. These devices are often utilized in space heaters. Through research and experimentation, the present inventors found that increasing the number of blades on the fan increases the number of chambers in which to mix the gases, thereby improving mixing results. Increasing the number of blades also enables use of open/closed gas valves, such as for example solenoids, eliminating the need for a venturi or similar structure. However, the present inventors also found that increasing the number of blades creates unwanted noise. More specifically, a pressure pulse is created when the blade moves past a stator. Increasing the number of blades increases the number of pressure pulses, thus increasing blade pass frequency which produces an unpleasant sound quality. The periodicity of evenly spaced blade pass events creates tone prominence, which the inventors found can be loud and potentially annoying.
The present disclosure results from the inventors' efforts to optimize radial mixing of the air and gas, while minimizing fan noise.
The gas burner device 16 also has a gas burner 44 that extends into the body 42 and heats the heat exchanger 40. The gas burner 44 has an elongated metal flame tube 46 into which a fully pre-mixed air-gas mixture is conveyed for combustion. The manner in which the air-gas mixture is mixed and conveyed to the gas burner 44 is a principle subject of the present disclosure and is further described herein below with reference to
An ignition and flame sensing electrode 56 is disposed in the flame tube 46, proximate to the burner skin 52. The electrode 56 extends through a through-bore in the burner deck 48 and is coupled to the burner deck 48. The type of electrode 56 and the manner in which the electrode 56 is coupled to the gas burner 44 can vary from what is shown. The electrode 56 can be a conventional item, for example a Rauschert Electrode, Part No. P-17-0044-05. The electrode 56 has a ceramic body 60 and an electrode tip 62 that is oriented towards the burner skin 52. The electrode 56 is configured to ignite the air-gas mixture as the air-gas mixture passes through the flame tube 46 via the aeration holes 50. The resulting burner flame 54 is thereafter maintained as the noted air-gas mixture flows through the burner skin 52.
In some non-limiting examples, the electrode 56 can be configured to measure the flame ionization current associated with the burner flame 54. Specifically, the electrode tip is placed at the location of the burner flame 54 with a distance of 2.5+/−0.5 mm between the electrode tip and the burner skin 52. A voltage of 275+/−15V is applied across the electrode 56 and burner skin 52, with the electrode 56 being positive and the burner skin 52 being negative. The chemical reactions that occur during combustion create charged particles, which are proportional to the air/fuel ratio of a given fuel. The potential difference across the gas burner 44 can be used to measure and quantify this. The electrode 56 is configured to measure the differential and, based on the differential, determine the flame ionization current, as is conventional and known in the art. The flame ionization current is inversely proportional to the “equivalence ratio”, namely the ratio of actual air-to-fuel ratio to stoichiometry for a given mixture. Lambda is 1.0 at stoichiometry, greater than 1.0 in rich mixtures, and less than 1.0 at lean mixtures. Thus a decrease in flame ionization current correlates to an increase in the equivalence ratio, and vice versa.
Referring now to
Referring to
It will thus be understood by those having ordinary skill in the art that the gas burner device 16 is a “fully premix” gas burner device in which all the gas (e.g. LPG) is introduced via the control valves 80 and all air introduced into the flame tube 46 is mixed via the fan 64. The air and gas are mixed together to form the air-gas mixture, which is ignited by the electrode 56 to produce the burner flame 54. In the illustrated example, the air and gas initially are brought together in an upstream gallery 55 (see
In certain non-limiting examples, the gas burner device 16 includes a computer controller 82, shown in
The gas burner device 16 can further include an operator input device 84 for inputting operator commands to the controller 82. The operator input device 84 can include a power setting selector, which can include for example a push button, switch, touch screen, or other device for inputting an instruction signal to the controller 82 from the operator. Such operator input devices for inputting operator commands to a controller are well known in the art and therefore for brevity are not further herein described. The gas burner device 16 can further include one or more operator indicator devices 85, which can include a visual display screen, a light, an audio speaker, or any other device for providing feedback to the operator.
In use, the controller 82 is configured to receive an input (e.g. a power setting selection) from an operator via the operator input device 84. In response to the input, the controller 82 is further configured to send a control signal to the fan 64 to thereby modify (turn on or increase) the speed of the electric motor 66. The controller 82 is further configured to send a control signal to the control valves 80 to cause one or both of the solenoid coils in the control valves 80 to open and thus provide a supply of gas. The controller 82 is further configured to cause the electrode 56 to spark and thus create the burner flame, and then monitor the flame current from the burner skin 52 and electrode 56, thus enabling calculation of the above-described flame ionization current, in real time. Based on the flame ionization current, the controller 82 is configured to further control the speed of the fan 64 (via for example the motor 66). Each of the above functions are carried out via the illustrated wired or wireless links, which together can be considered to be a computer network to which the various devices are connected. Operation of the gas burner 44 warms the heat exchanger 40 including the body 42 and fins 43. Operation of the fan 28 causes air to be conveyed through the housing 18 and across the fins 43. The relatively warm fins 43 exchange heat with the relatively cool air, thus warming the air prior to discharge via the warm air outlet 26.
Referring now to
A channel 98 is formed in the end wall 73 and connects the air-gas mixture inlet 88 to the air-gas mixture outlet 90. The air-gas mixture flows through the channel 98 from the air-gas mixture inlet 88 to the air-gas mixture outlet 90 in generally the same direction as the direction of rotation of the blades 70 (counter-clockwise in
The channel 98 has an inlet end 100 at the air-gas mixture inlet 88 and an outlet end 102 at the air-gas mixture outlet 90. The inlet end 100 generally has a crescent shape with a narrow tip 104 located at the air-gas mixture inlet 88, more specifically at the radially inner end 105 of the noted window. The inlet end 100 gradually widens as it extends along the channel 98 away from the narrow tip 104. In particular, the inlet end 100 has a radially outer edge 106 and a radially inner edge 108. The radially outer edge 106 extends in a straight line along the window 89 and then radially outwardly curves towards the radially outer end 96 of the end cap 72. The radially inner edge 108 forms a generally straight tangent from the noted window 89 and then tightly curves around the radial center 94 of the end cap 72. The outlet end 102 has a crescent shape with a narrow tip 110 located at the air-gas mixture outlet 90. The outlet end 102 gradually narrows towards the narrow tip 110. In particular, the outlet end 102 has a radially inner edge 112 and a radially outer edge 114. In the counter-clockwise direction, the radially inner edge 112 extends generally radially outwardly and then curves more severely towards the narrow tip 104. The radial outer edge 114 curves generally alongside the radial outer end 96 of the end cap 72.
Referring to
Advantageously, the air and gas are introduced into the interior 69 close to the radial center 94, which facilitates mixing. The relatively large number of blades (twenty-three) provides a large number of chambers for mixing. In particular, the larger number of relatively small chambers allows for greater mixing than would a relatively fewer number of larger chambers. A larger number of blades would create a higher blade pass frequency. However, as explained above, the sinusoidal blade spacing advantageously minimizes acoustic noise by spreading the acoustic pressure pulses across the frequency spectrum, resulting in reduced tone prominence at any given blade pass frequency. The end cap 72 includes the specially configured channel 98, which gradually increases the volume in any individual chamber within the fan. This reduces the amplitude of the pressure pulse generated by a blade pass. In the example shown, the chambers are never open to the outlet and the inlet side of the device at the same time because the inlet 88 and outlet 90 are not radially overlapping. Thus, the design optimizes noise, vibration and harmonics requirements from the user while delivering the required performance.
Although specific advantages have been enumerated above, various embodiments may include some, none, or all of the enumerated advantages. Other technical advantages may become readily apparent to one of ordinary skill in the art after review of the following figures and description. Modifications, additions, or omissions may be made to the systems, apparatuses, and methods described herein without departing from the scope of the disclosure. For example, the components of the systems and apparatuses may be integrated or separated. Moreover, the operations of the systems and apparatuses disclosed herein may be performed by more, fewer, or other components and the methods described may include more, fewer, or other steps. Additionally, steps may be performed in any suitable order. As used in this document, “each” refers to each member of a set or each member of a subset of a set.
To aid the Patent Office and any readers of any patent issued on this application in interpreting the claims appended hereto, applicants wish to note that they do not intend any of the appended claims or claim elements to invoke 35 U.S.C. 112(f) unless the words “means for” or “step for” are explicitly used in the particular claim.
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