Patent Grant
10480782
The present invention relates to fire constructions, and more particularly to fire constructions or stoves used to burn solid fuel such as coal, wood, biomass fuels and the like.
The combustion of solid fuels within the enclosed combustion chambers or fireboxes of known solid fuel fires or stoves is generally considered to be reasonably effective in terms of the generation of heat, but often the amounts of pollutants that can be exhausted, such as carbon monoxide and particulates, can be unsatisfactory.
Air is of course required to support combustion within an enclosed combustion chamber, and conventionally fire constructions, particularly those designed for burning coals, provide for a primary air supply to support the primary combustion of the fuel. This is typically provided from a position beneath the fuel and is generally referred to as primary air.
Primary air alone however is often considered insufficient to achieve satisfactory levels of combustion of certain fuels such as coals, and so fire constructions designed to burn such fuels typically have a secondary air supply provided at a position above the fuel to provide some secondary support for combustion. Such secondary air is used in certain known fire constructions to provide an air wash over the inside of a glass door of the construction, to help keep the glass door relatively clear of soot and other visible by-products of the combustion process.
In certain fire constructions such as those designed to burn wood, such secondary air provides the main air supply supporting combustion, in which case an aforesaid primary air supply is not provided.
In certain known fire constructions a further, often termed tertiary air supply is provided to present tertiary air to further support the combustion process. In fire constructions that have both primary and secondary air supplies, the tertiary air supply offers a third air supply to the combustion process, as its name suggests. In fire constructions that have no primary air supply and just a secondary air supply, the tertiary air supply represents a second air supply to the combustion process. However, it is still often referred to as tertiary air.
In both such constructions, the tertiary air's main function is to support combustion of particulate and other by-products of the main combustion processes within the fire construction.
In accordance with aspects of the present invention there is provided a fire construction comprising a firebox defining a combustion chamber in which fuel can be burnt, a first air supply means for delivering air into the combustion chamber to support combustion of fuel therein, and a second air supply means for supplying additional air to further support combustion of fuel within the combustion chamber, the second air supply means comprising a supply conduit connecting the combustion chamber with an air supply, the supply conduit having a cross section that increases as the supply conduit opens into the combustion chamber.
The second air supply means may comprise a plurality of supply conduits. The supply conduit or at least one of the supply conduits may extend through a wall of the firebox. The supply conduit or at least one of the supply conduits may be formed as (a) passage(s) within the wall. Alternatively or in addition the supply conduit(s) may comprise a body defining (a) passage(s) located through the wall.
The supply conduits may be aligned, in a generally linear arrangement, which may extend generally horizontally in use. The supply conduit or at least one of the supply conduits may be located in a rear wall of the firebox, which rear wall defines at least in part an inner rear surface of the firebox. Alternatively or in addition the supply conduit or at least one of the supply conduits may be located in one or more of the side walls of the firebox, which side wall(s) define (an) inner side surface(s) of the firebox.
The supply conduit or at least one of the supply conduits may open into the combustion chamber at a location above fuel in the fire and may be located in an upper region of the rear wall and/or side wall(s), which may be at or near the top of the inner rear surface and/or inner side surface(s) of the firebox. The arrangement of supply conduits may extend across the inner rear surface and/or inner side surface(s) at a location at or near the top thereof.
The cross section of the supply conduit or at least one of the supply conduits increases in the direction the additional air generally flows through the supply conduit into the combustion chamber. The cross section may increase in the general direction of and may be along the longitudinal axis of the supply conduit(s).
The cross section may flare outwardly as a conduit opens into the combustion chamber to have a flared region.
The flared region may extend from partway along the length of the conduit to the combustion chamber. The supply conduit may comprise a region of generally constant cross section, such as in the form of a circular passage or tubular section from which extends the flared region.
The flared region may be generally frustoconical.
The flared region may have an inner surface which is stepped, to provide at least one stepped increase in cross section.
The inner surface may comprise a sequence of stepped sections in which the section(s) may extend at an angle of between 0° and 90° to the directional axis of the conduit through the rear wall.
The angle may differ between respective step sections. At least one step section may extend at an angle of substantially 90° to the said directional axis, other, possibly adjacent step sections may extend at an angle of between 30° and 60° and may be approximately 45° to said directional axis.
The supply conduit or at least one of the supply conduits may open into the combustion chamber on the inner rear surface. Alternatively or in addition the supply conduit or at least one of the supply conduits may open into the combustion chamber on one or more of the inner side surfaces.
Alternatively or in addition, the or at least one of the supply conduits may extend through to protrude from the inner rear surface to extend into the combustion chamber.
Alternatively or in addition the or at least one of the supply conduits may extend through to protrude from the or at least one of the inner side surfaces to extend into the combustion chamber.
Supply conduit(s) that open on the inner rear surface and/or inner side surface(s) may open in a recessed region of the inner rear surface and/or inner side surface(s). The recessed region may comprise an in-use upper, generally straight edge, and may further comprise an in-use lower, generally profiled edge that follows the profile(s) of the supply conduit(s) as they open onto the surface, in generally spaced relation thereto to define the recess on the surface, around the supply conduit(s).
The supply conduit or at least one of the supply conduits may have a generally circular cross section around the directional axis thereof as they extend through the firebox.
Alternatively or in addition, the, one or at least some of the supply conduit(s) may have an elongate cross section across the direction of extension thereof through the firebox. Such conduit(s) with elongate cross section may define a slot or similar elongate opening that opens into the combustion chamber. Such supply conduits may share a flared region.
The supply conduit(s) may connect the combustion chamber to an air supply, which may be ambient, atmospheric air, externally of the firebox. The air supply may also supply air for the first air supply means.
The firebox may comprise a base, a top, two side walls, a front and a rear wall, which between them define the combustion chamber.
Aspects of the present invention will now be described by way of example only with reference to the accompanying drawings in which:
The present invention provides a fire construction 10 comprising a firebox 12 defining a combustion chamber 14 in which fuel (not shown) can be burnt, a first air supply means 16 for delivering air into the combustion chamber 14 to support combustion of fuel therein, and a second air supply means 18 for supplying additional air to support combustion of fuel within the combustion chamber 14, the second air supply means 18 comprising a supply conduit 20 connecting the combustion chamber 14 with an air supply 22, the supply conduit 20 having a cross section 24 that increases as the supply conduit 20 opens into the combustion chamber 14.
In more detail,
The general construction of the firebox 13 is that of conventional fireboxes and comprises a grate G or other support for the fuel (not shown) and an ash box A beneath the grate to collect ash that falls through the grate from combustion.
A flue or chimney F is provided through which the gaseous and other products of combustion are exhausted.
The first air supply means 16 is what is conventionally termed in the art a primary air supply and is of conventional design, and will not be discussed in particular detail in this specification. However, essentially it supplies primary air, typically from externally of the fire construction, and usually through openings in the base or the front of the firebox into the combustion chamber 12. Primary air is typically drawn into the firebox through the primary air supply means 16 and into the combustion chamber 14 generally from beneath, up and through the fuel. Convections caused by combustion draw the primary air into the firebox 12. A typical primary air flow is illustrated diagrammatically with the arrows P.
In certain embodiments a secondary air supply means (not shown) is provided, which again is of conventional design and will not be discussed in particular detail herein. Such secondary air supply can provide air into the combustion chamber, usually at the front of the combustion chamber, to further support combustion and/or provide an air wash, typically over the inside of the front 32. Such secondary air supply is distinct from the second air supply of the present invention.
In such embodiments the second air supply means of the present invention provides additional air which may typically be understood in the art as tertiary air.
In certain other embodiments such a secondary air supply means may provide the main air supply for combustion within the construction. This can be so in fire constructions designed to burn fuels such as wood or wood-derived fuels, and in such constructions this secondary air supply represents the first air supply means within the present invention.
The top 28 and the sides 30 may be of generally conventional construction, typically comprising the main structural walls of the firebox, often of cast iron or other suitable material. Fire brick 35 or other insulating materials typically lines at least the sides 30 and rear 34.
The front 32 is again of generally conventional design, typically comprising a door that can be selectively opened and closed for access into the combustion chamber, such as for the placement of fuel for combustion.
The front 32 is illustrated as having a transparent viewing panel, which is typically of fire glass, and in those embodiments that have a secondary air supply directed to provide an air wash over the inside surface of the glass, this helps to prevent visible by-products such as soot from resting on the glass.
The second air supply means 18 of the present invention provides for improved combustion and provides a general reduction in overall pollutants expelled from conventional fire constructions, as will now be described.
With reference to
With particular reference to
The cross section of each supply conduit 20 increases in the direction the additional air generally flows through the conduit 20 into the combustion chamber 14. In this embodiment, the cross section flares outward as each conduit 20 opens into the combustion chamber 14, giving each such conduit 20 a flared region 38 at the end thereof that opens into the combustion chamber 14.
The flared region 38 of a supply conduit 20 has an inner surface 40 which is stepped, to provide stepped increases in cross section.
As can be seen in
Section 42a extends generally perpendicularly from an inner section 43 formed through the rear wall 34 and of generally constant cross section to section 42b which extends generally perpendicularly therefrom and generally parallel to the directional axis X of the conduit 20 to in turn meet section 42c which extends outward therefrom at a constant angle from the directional axis X to define a generally frustoconical section of the conduit 20. The angle illustrated is generally 45°. The adjacent section 42d extends outwardly from the section 42c in a direction generally perpendicular to the axis X and section 42e extends from section 42d to be generally perpendicular to the section 42d and parallel to section 42b of the axis X. The sections 42a and 42b define a generally tubular region of the conduit 20 of constant cross section which is connected to another generally tubular region defined by section 42d and 42e by the generally frustoconical region defined by the section 42c. These regions are all defined within the fire brick 35.
Each conduit 20 opens about the section 42e, in a recessed region 44 of the rear surface 36. The recessed region 44 provides an effective extension of the conduits 20, both in their effective length and cross sectional area.
Each supply conduit 20 extends from an outer end 20a which communicates with the air supply which is illustrated generally as 22 in
The air supply 22 is ambient or atmospheric air which is typically sourced from externally of the fire construction 10, from the space such as the room in which the construction 10 is sited. Additional conduit sections 20c may extend from the rear wall 34 to communicate with the air supply 22.
In use, the second air supply means 18 provides a flow of additional air from the air supply 22, through the conduits 20 and into the combustion chamber 14 where the conduits 20 open into the combustion chamber 14.
Arrows T illustrate diagrammatically the main flow of additional air through the conduit(s) 20. General convections within the combustion chamber draw the air through the conduits 20.
As will now be discussed, the profile of the cross section of a conduit 20 will determine the typical air flow therethrough. For example, profiles that define corners or ridges, such as those discussed above, will influence the flow T by causing swirls or eddies within the air flow. The profile can therefore be engineered to provide such desired turbulence.
The increase in cross section of a supply conduit 20 as it opens into the combustion chamber 14 is found to provide efficient combustion, typically final stage combustion, particularly of particulates and other pollutants rising up the rear of the firebox 12 as by-products of the primary or main combustion process within the chamber 14.
Without wishing to be bound by theory, the increase in the cross sectional area of a supply conduit 20 is understood to result in a reduction in the speed of the air flow as it enters and moves through the region where the cross sectional area increases (diameter widens). This reduction in speed is concomitant with an increase in pressure.
These effects are understood to provide for entrainment of partly combusted particulates rising up the rear of the firebox, as by-products of primary combustion, into the additional air flow, which has been found to increase the amount and efficiency of this secondary or tertiary combustion, thus reducing the percentage of particulates eventually exhausting from the fire construction 10.
It is also found that the second air supply means 18 of the present invention enables a satisfactory level of secondary or tertiary combustion to be achieved with a reduced amount of additional air, which improves thermal efficiency by allowing less external air into the combustion process.
Increasing the cross sectional area of a conduit 20 in a series of discrete steps, as illustrated, is understood to result in turbulence as the air flows therethrough as the air experiences the corners and recesses presented by the steps, which turbulence helps to mix the additional air with the fuel gases and particulates produced by the primary combustion to further support combustion.
The reduction in air speed and the increase in pressure within the flared region 38 continues into the recessed region 34, helping to retain the by-products of combustion in the vicinity of the incoming air, resulting in a longer dwell time and promoting better mixing of particulates, gases and air, prolonging the combustion process and thus presenting better secondary or tertiary combustion and reduction of particulates and other pollutants.
It has also been found that establishing these differential air pressures/velocities also helps to reduce the carbon monoxide levels that are exhausted from the fire construction.
The fire construction 110 is generally of similar construction to the aforedescribed fire construction 10 and corresponding features are identified with corresponding reference numerals.
In this embodiment the conduits 120 open onto the rear inner surface 36 through a shared elongated flared cross section 124.
Each supply conduit 120 comprises one of a linear series of inner sections 143 which extend through the rear 34 of the fire construction 110 in generally similar manner to the sections 43 described above.
As can be seen in
Providing the conduit 310 formed as a separate body to the rear 34 enables the body 60 to protrude from the inner rear surface 36 into the combustion chamber 14 to enable the additional air to be expelled into the combustion chamber 14 at a location that is forward of the rear surface 36.
This can provide for precise location of the point of entry of the additional air to be engineered to still further help enhance combustion and reduce pollutants in particular fire constructions.
The fire construction 110 is similar to the fire construction 10 detailed above, and shared features are marked with the same reference numerals. However, in this construction 110, the supply conduits 20 extend through the side wall 30, rather than the rear 34. Each of the supply conduits 20 in this embodiment are the same as those detailed above with reference to the construction 10, although the number and/or size of the supply conduits 20 may be reduced compared to those provided in construction 10 due to the side walls typically being smaller in width (front to back) than the rear 34 (side to side).
For illustration purposes only one side wall 30 is shown, but it will be appreciated that supply conduits can be provided in the side wall 30 and the opposing side wall (not illustrated) so that air is supplied into the combustion chamber 14 from both sides.
It will be still further appreciated that in accordance with certain aspects of the present invention one or more supply conduits can be provided in both the rear 34 and one or both of the side walls 30.
Features described in the preceding description may be used in combinations other than the combinations explicitly described. Although functions have been described with reference to certain features, those functions may be performable by other features, whether described or not. Although features have been described with reference to certain embodiments, those features may also be present in other embodiments, whether described or not.
Various modifications may be made without departing from the spirit or scope of the present invention.
For example, the number and relative positioning of the supply conduits can be varied and engineered according to the desired characteristics of the additional air entry positions. The profile and design of the inner surface of the increased cross section of each conduit can be designed and engineered to provide the desired flow characteristics of the additional air flow.
Whilst endeavouring in the foregoing specification to draw attention to those features of the invention believed to be of particular importance it should be understood that the Applicant claims protection in respect of any patentable feature or combination of features hereinbefore referred to and/or shown in the drawings whether or not particular emphasis has been placed thereon.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1312870.7 | Jul 2013 | GB | national |
| 1318922.0 | Oct 2013 | GB | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/GB2014/052107 | 7/10/2014 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2015/008036 | 1/22/2015 | WO | A |
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| 7047891 | Vatsky | May 2006 | B2 |
| 7878130 | Yamamoto | Feb 2011 | B2 |
| 8430665 | Payne | Apr 2013 | B2 |
| 20090084346 | Zhou | Apr 2009 | A1 |
| 20120137938 | Orii | Jun 2012 | A1 |
| Number | Date | Country |
|---|---|---|
| 556914 | Feb 1960 | BE |
| 223503 | Sep 1942 | CH |
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| Entry |
|---|
| The International Search Report and Written Opinion issued in International Application No. PCT/GB2014/052107; dated Jan. 14, 2015. |
| The Combined Search and Examination Report under Section 17 & 18(3) issued in corresponding Great Britain Application No. GB1318922.0; dated Nov. 15, 2013. |
| The examination report issued in the corresponding European Patent Application No. 14739535.4; dated Feb. 16, 2018. |
| Number | Date | Country | |
|---|---|---|---|
| 20160186989 A1 | Jun 2016 | US |
