The present invention relates generally to a chimney liner adaptor for protecting the open end of the annular space of a chimney flue from the ingress of undesirable elements.
It is well known that chimney caps are often desired to prevent the ingress of undesirable elements into the upper end of a chimney flue. For example, the undesirable elements may include birds, squirrels, and rain. It is also known that chimney caps are desired to prevent the egress of embers from the upper end of the chimney flue. In many chimney systems, a chimney liner is disposed within a chimney flue. For example, when a masonry chimney flue develops cracks or leaks in its side walls due to deterioration over time or other reasons, the installation of a chimney liner within the flue is a cost-effective way to repair the deteriorated flue. The hot gases and combustion products are contained within the liner. Such liners are often round conduit or pipe made of corrosion resistant material such as stainless steel.
In some chimney systems, the chimney liner is disposed within a multi-wall factory-built type chimney. Generally, a factory-built chimney is a double-walled round conduit or pipe, with the inner wall spaced from the outer wall. The inner wall is the flue for the hot gases and combustion products. The annulus formed between the two pipe walls acts as insulation, so that the outer wall stays cool enough to be installed in close proximity, e.g., within one to two (1-2) inches, of combustible materials. Also, cooling air may flow through the annulus by forced or natural convection. Some factory-built chimney pipes have three walls and/or insulation positioned between two of the walls. For example, a factory-built chimney for wood-burning fireplaces is marketed by Hearth Technologies Inc., dba Heatilator, of Mt. Pleasant, Iowa.
When a liner is installed within a factory-built chimney, another annular “inner chimney space” is formed between the outside of the chimney liner and the inside wall of the factory-built chimney. Therefore, it is desirable to permit the movement of cooling air through this inner chimney space to exit to the outside environment. However, when a chimney cap is attached to such a chimney system to prevent the ingress of undesirable elements into the chimney liner, it may block the air circulation to the inner chimney space. Chimney caps are known that permit the circulation of air to the inner chimney space. However, these known devices fail to prevent the ingress of undesirable elements into the inner chimney space. Therefore, it would be desirable to have a chimney liner adaptor that prevents the ingress of undesirable elements into the inner chimney space and also permits the use of a chimney liner cap to prevent the ingress of undesirable elements into the chimney liner.
The invention provides a chimney liner adaptor that prevents the ingress of undesirable elements into the inner chimney space but permits an air exchange between the inner chimney space and the outside environment. The invention also permits the use of a chimney cap to prevent the ingress of undesirable elements into the chimney liner. According to one aspect of the invention, a chimney liner adaptor comprises an apertured element for permitting air flow between a chimney and the outside environment; and a device for supporting the apertured element on the chimney.
In another aspect, the chimney liner adaptor comprises a first perforated disc in a first plane having an aperture; and a second disc having a second aperture, the second disc being disposed above and substantially parallel to the first plane, the second disc being connected to the first disc, the diameter of the first aperture being substantially equal to the diameter of the second aperture; and wherein the second disc is adapted to be disposed on top of the chimney annulus, and the first and second apertures are adapted to receive a chimney liner.
The present invention can be used to terminate a chimney lining in a multi-wall factory built pipe installation without obstructing the designed circulation, while at the same time preventing birds and small animals from entering the chimney walls. This may be accomplished by the use of stainless steel mesh covering the entire opening on the underside of the adaptor. The operation of the liner adaptor achieves the designed air flow of the multi-wall lining pipe by keeping the air flow separated from the smoke and fumes of the fire.
A further objective is to allow a chimney cap, for example a HomeSaver® Pro™ Guardian™ cap, to be installed on multi-wall factory-built pipe lined with stainless steel pipe. The use of a top clamp and storm collar with the liner adaptor allows installation of the readily available chimney caps by chimney professionals. An additional benefit of the liner adaptor is the added support to the relining pipe achieved by the use of the top clamp and the storm collar. The top clamp grips the lining pipe and supports the pipe by distributing the weight to the storm collar which is then distributed to the adaptor and finally to the multi-wall pipe.
These and other features and advantages of the invention will be more readily understood from the following detailed description of a preferred embodiment which is provided in connection with the accompanying drawings.
The inner chimney space can also include the annular space 385 between the inner wall 170 and the liner 120. Part of the chimney liner adaptor 130 that extends radially from the collar 340 (
The storm collar 160 is a bezel-shaped metal, preferably formed of stainless steel, having an inner diameter slightly larger than the diameter of the liner 120 and an outer diameter smaller than the diameter of disc 320 (
The top clamp 150 is formed from two “c” clamps. Each “c” clamp is formed from a rectangular metal strip having three sections, the first and third sections being substantially co-planar. The second section, disposed between the first and third sections, is substantially arc shaped, where the diameter of the arc is substantially equal to the diameter of the liner 120. The top clamp 150 is implemented by the two “c” clamps joined such that the respective arcs form a cylinder, respective first sections abut, and the respective third sections abut. These respective sections are mechanically coupled after installation by screws, nuts and bolts, or the like. In a preferred embodiment, each first and third sections of both “c” clamps have a respective aperture 151, 153 which are substantially similar in diameter and adapted to receive a screw. The apertures 151, 153 are disposed such that when the first section of one “c” clamp is in contact with the third section of the other “c” clamp the respective centers of apertures 151, 153 are substantially aligned. In another aspect, a nut 154 is connected to the third section of each “c” clamp. The aperture of nut 154 has a diameter that is substantially similar to the diameter of the apertures 151, 153. The aperture of each nut 154 is substantially coaxial to the apertures 151, 153.
Referring now to
The mesh disc 310 is preferably formed from a substantially planar, perforated material, preferably stainless steel. The perforated material may be, for example, an expanded metal mesh, a metal screen, stamped metal screen, rugged netting, or the like. The mesh disc 310 has a diameter sufficiently larger than the diameter of the chimney pipe 180 (
The disc 320 has a diameter sufficiently larger than the diameter of the chimney pipe 180. The disc 320 has an aperture 356 having a diameter that is smaller than the diameter of the inner wall 170 and a diameter larger than the liner 120. The diameter of the aperture 352 of the mesh disc 310 corresponds to, and is substantially equal to, the diameter of the aperture 356 of the disc 320. The outer diameter of the mesh disc 310 corresponds to, and is slightly smaller than, the outer diameter of the disc 320. In a preferred embodiment, the respective diameter of the apertures 352, 356 of discs 310, 320 is substantially equal to seven and eleven sixteenths (7 11/16) inches. In a preferred embodiment, the outer diameter of disc 310 is substantially equal to sixteen (16) inches and the outer diameter of discs 320 is substantially equal to sixteen and three quarters (16¾) inches. The diameters of discs 310, 320 is such that liner adapter 130 is adapted to be used with different chimney systems having different sized outer walls 180.
The band 330 is formed from a substantially rectangular strip of metal, preferably stainless steel, to form a cylinder. The length of band 330 corresponds to the (exterior) radius of the disc 310. In a preferred embodiment the height of the band 330 is substantially equal to one and one half (1½) inches. The band 330 may also have a flange 332 extending from one end of the cylinder being formed away from the exterior. The flange 332 is approximately one quarter (¼) inch in the radial direction.
The collar 340 is substantially cylindrically shaped having on one end a small flange projecting away from, and substantially perpendicular to, the exterior wall of the collar 340. In a preferred embodiment, the collar 340 is formed of stainless steel. The diameter of the collar 340 is substantially equal to the respective diameters of the apertures 352, 356 of the discs 310, 320. In a preferred embodiment, the length of the collar 340 is substantially equal to five and one half (5½) inches and the flange is approximately one quarter (¼) inch in length. As noted above, however, the present invention should not be limited to the details of the illustrated embodiments.
The mesh support 350, or standoff, may be formed from rectangularly shaped metal pieces. In the illustrated embodiment, each rectangularly shaped metal piece is bent a first time forming a first section that is substantially perpendicular to a second section. The metal piece is bent a second time along an imaginary line that is parallel to an imaginary line formed by the first bend. The third section is substantially perpendicular to the second section and bent away from the side of section two where section one is disposed. The plane formed by section one is substantially parallel to the plane formed by section three.
The disc 320, which may be stamped from sheet metal, is disposed in a plane parallel to and above the plane formed by disc 310. The center point of the aperture of disc 320 is substantially aligned with the center point of the aperture of disc 310. Four mesh supports 350 couple disc 310 to disc 320. Preferably, each mesh support 350 is substantially at a radial position on discs 310, 320 ninety (90) degrees from the neighboring mesh support 350. Each respective first section of a mesh support 350 is substantially parallel to a plane formed by disc 310 and substantially flush and coupled to the disc 310. Each respective third section of a mesh support 350 is substantially parallel to a plane formed by disc 320 and substantially flush and coupled to disc 320. In the illustrated embodiment, mesh supports 350 are coupled to discs 310, 320 by resistance welding.
Collar 340 is disposed through the apertures of discs 310, 320 such that the bottom of the flange on collar 340 is coupled with the top surface of disc 320. The length of the collar 340 extends through the aperture on discs 310, 320 and the collar extends below disc 310. In a preferred embodiment, the flange of the collar 340 is resistance welded to the surface of disc 320.
The band 330 is bent lengthwise and shaped into a cylinder where one lengthwise end of the band 330 abuts and is coupled to the other lengthwise end of the band 330. The bottom circumference of the cylinder formed by the band 330 is disposed and may be coupled to the circumference of the disc 310 by resistance welding. The top circumference of the cylinder formed by the band 330 and the flange is disposed and coupled to the bottom side of the disc 320, preferably by resistance welding.
The liner adaptor 130 is disposed such that the liner 120 is disposed within and extends through the collar 340. The collar 340 of the liner adaptor 130 is disposed within the inner wall 170. The bottom side of the liner 130, e.g., the mesh disc 310, is disposed on the top of either the inner or outer walls 170, 180, depending on which is higher. In many chimney systems, the inner and outer walls 170, 180 are substantially the same height. The diameter of the mesh disc 310 should be substantially larger than the diameter of the outer wall 180. There is an annular region 365 in the liner adaptor 130 bounded by the liner 120 and the band 330 and the mesh disc 310 and the disc 320. Air is permitted to flow freely from/to the inner chimney space through the annular space 365.
The storm collar 160 is disposed above and abuts the top surface of the liner adaptor 130, and has an outward slope in a downward direction. The top clamp 150 is disposed above the storm collar 160. A benefit of the illustrated arrangement is that added support is provided for the upper portion of the liner 120. The upper portion of the liner 120 is supported in part by the top clamp 150 and the storm collar 160. The top clamp 150 grips the liner 120 and supports the liner 120 by distributing the weight to the storm collar 160 which is then distributed to the liner adaptor 130 and finally to the multi-wall pipe 180. The chimney cap 110 is disposed above the top clamp 150 and coupled to the liner 120.
As seen in
Air from annular space 385 can be carried between the inner wall 170 and the liner 120 and through the mesh disc 310 on the interior side of the inner wall 170 and subsequently through the mesh disc 310 on the exterior side of the outer wall 180 into the environment. The flow of air egressing annular space 385 is indicated by arrow 392. It may also be desirable that air be permitted to flow though space 385 in the reverse direction. The air circulation may be dependent upon the existence and size of the annular area between the collar 340 and the inner wall 170. However, the presence and use of the mesh disc 310 as part of the liner adaptor 130 prevents undesirable elements, e.g., rodents, from outside the chimney system from entering into the chimney system.
While the invention has been described and illustrated with reference to specific exemplary embodiments, it should be understood that many modifications and substitutions can be made without departing from the spirit and scope of the invention. The invention is not to be considered as limited by the foregoing description but is only limited by the scope of the claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 10/347,517, filed Jan. 21, 2003, now U.S. Pat. No. 6,852,023, the disclosure of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | 10347517 | Jan 2003 | US |
Child | 11050798 | Feb 2005 | US |