The present application relates generally to switch mechanisms and, more particularly, to igniter switches for gas cooking appliances. Most specifically, the present invention relates to switch mechanisms useful for outdoor applications as actuating switches for igniters of gas cooking appliances.
Gas cooking appliances are known to have a manifold assembly made of metal tubing or pipes that directs gas from a main gas source to the individual burners. The manifold includes one gas valve for each burner. When cooking, the consumer controls the flow of gas, and hence the levels of the cooking flame by manually adjusting the gas valve for a particular burner. The valve is fitted with a plastic knob or handle of some sort to facilitate the consumer interface with the valve.
To begin the cooking process, the flow of gas must be started and then ignited immediately. In the past, the gas was ignited simply with a match or other open flame source. Thereafter, gas cooking ranges were provided with a standing pilot light that automatically ignited the gas at the burner when the gas flow reached the burner. More recently, cooking appliances have been provided with electronic ignition systems to ignite the gas. Electronic ignition systems are used to ignite gas at the burners of gas cooking appliances without the inconvenience of hand lighting with a match or other ignition source. Electronic ignition modules also avoid the wastefulness of standing pilot lights that consume fuel when a burner is not in use. In an electronic ignition system, a spark igniter initiates a spark or series of sparks at the same time as gas flow is initiated to the burner assembly.
When a gas appliance is used for indoor or weather-protected installations, known electronic gas ignition systems using spark igniters, electronic ignition modules and switch harnesses have been used effectively. However, it is desirable to have similar convenience for igniting outdoor gas cooking appliances, and known ignition modules and switch harnesses have not provided sufficient weather resistance for prolonged outdoor use.
Basic reed switches are known. A reed switch can have switch contacts in an enclosed glass or other weatherproof housing. The reed switch contacts are opened and closed through the manipulation of a magnet, which causes the switch elements to be magnetized and contact one another or to be non-magnetized and separate from on another. It is known to use the basic principles of a reed switch in a rotary operating condition such that the switch can be moved from an open condition to a closed condition by rotating a knob containing a magnet therein in close proximity to the vessel containing the reed switch contacts.
A problem with known rotary actuated reed switches is that the switch contacts are close to the surface of the appliance so that the control knob containing the magnet is in close proximity thereto. It is known to use magnets in other accessories, such as note and recipe card holders, outdoor accessory lights for cooking grills, utensil holders and the like. If an accessory containing a magnet of sufficient strength is placed near the control knob containing the magnet for the reed switch, the reed switch can be actuated inadvertently by the magnet on the accessory, or the magnet on the accessory can interfere with the proper operation of the reed switch through rotation of the control knob. Further, the magnet can be dislodged or lost when the control knob is removed for cleaning. If the knob is damaged and requires replacements, the consumers options for a replacement part are limited if operation of the reed switch is to be maintained.
The present invention provides a remote actuated reed switch associated with a gas flow control valve for a gas cooking appliance in which a magnet slides within a channel guided in movement by a curved slot of a rotary actuator to move the reed switch from an open condition to a closed condition and back to an open condition appropriate for the gas flow control moving from a closed condition through an igniter position and to various positions for controlling gas flow and flame conditions.
In one aspect thereof, the present invention provides a gas appliance control assembly with a gas valve having a rotatable valve shaft and a reed switch having first and second reed switch contacts and a magnet movable relative to the first and second contacts. The reed switch includes a reed switch body defining a substantially straight channel and a reed switch rotary element having a cam track. The rotary element is associated with the valve shaft for rotation therewith, and is associated with the reed switch body for relative rotation thereto upon rotation of the valve shaft. The magnet is disposed partly in the channel and partly in the cam track.
In another aspect thereof, the present invention provides a gas appliance control assembly with a gas valve having an inlet, an outlet and a rotatable valve shaft and a reed switch in proximity to the gas valve. The valve shaft extends through the reed switch. The reed switch includes a reed switch body, a rotary switch element, first and second contacts, and a magnet movable relative to the contacts for opening and closing the contacts. The rotary switch element is associated with the valve shaft for co-rotation therewith and with the reed switch body and the first and second contacts for relative rotation with respect thereto. A substantially straight channel is defined in the reed switch body, and a cam track is defined in the rotary switch element. The magnet is disposed partly in the channel and partly in the cam track to traverse the channel and the track upon rotation of the valve shaft.
In a still further aspect thereof, the present invention provides a gas appliance with a burner assembly and a control assembly. The control assembly includes a gas valve controlling gas flow to the burner assembly, an electronic ignition module and a spark igniter electrically connected to the electronic ignition module and a reed switch electrically connected to the electronic ignition module. The reed switch has first and second switch contacts, a magnet movable relative to the first and second switch contacts, a fixed switch body, and a rotatable switch element. A valve shaft extends through the reed switch and adjustably controls gas flow through the gas valve upon rotation of the shaft. A gas manifold is in flow communication with the gas valve. A gas line connects the gas valve to the burner assembly. The rotatable switch element is secured to the valve shaft for co-rotation therewith, and defining a cam track. The fixed switch body defines a substantially straight channel. The magnet is disposed partly in the cam track and partly in the substantially straight channel.
An advantage of the present invention, in one form thereof, is providing a substantially weatherproof switch for an electronic igniter system on gas appliances.
Another advantage of the present invention, in another form thereof, is providing a remote operated switch in close proximity to an associated gas control valve for operating gas fired appliances.
Still another advantage of the present invention, in yet another form thereof, is providing a reed switch protected from inadvertent manipulation by extraneous magnets used around the appliance having the reed control switch.
Still another advantage of the present invention, in still another form thereof, is providing a reed switch and gas valve control assembly mechanism that can be used indoors and outdoors on a variety of appliances and devices.
Other features and advantages of the invention will become apparent to those skilled in the art upon review of the following detailed description, claims and drawings in which like numerals are used to designate like features.
Before the embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced or being carried out in various ways. Also, it is understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use herein of “including”, “comprising” and variations thereof is meant to encompass the items listed thereafter and equivalents thereof, as well as additional items and equivalents thereof.
Referring now more specifically to the drawings and to
Control assembly 12 includes a reed switch 20 operatively connected to an electronic ignition module 22 by main conductors 24, 26. Control assembly 12 further includes a known gas valve 28 for controlling flow of gas from a gas manifold 30 to burner assembly 14, and includes a gas valve inlet 32 in flow communication with manifold 30 and a gas valve outlet 34 in flow communication with burner assembly 14. Reed switch 20 and gas valve 28 are controlled jointly by rotation of a control knob 36 connected to, for rotation of a valve shaft 38. Rotation of shaft 38 operates reed switch 20, as will be described more fully hereinafter, and adjusts also the opening and closing of gas valve 28 to control the flow of gas, as those skilled in the art will readily understand.
Burner assembly 14 includes a gas burner 40 receiving gas flow from gas valve 28 via a gas line 42 connected to outlet 34 and burner 40. A spark igniter 44 is associated with gas burner 40 for igniting gas emitted from burner 40. Spark igniter 44 is connected to electronic ignition module 22 by a conductor 46. Electronic ignition module 22 and spark igniter 44 are of known design understood by those skilled in the art and will not be described in further detail herein. Upon activation by closing reed switch 20, electronic ignition module 22 supplies an electrical impulse to spark igniter 44 in close proximity to burner 40. The spark or sparks emitted from spark igniter 44 ignite gas flowing from gas burner 40 to initiate a flame at burner 40.
As shown in
As shown in
Switch body 72 defines a substantially straight slot or channel 76. Rotary switch element 74 defines a cam track or continuous path 78 having a tear drop shape. For illustrative purposes, channel 76 and cam track 78 are depicted in dotted lines in
A magnet 80 is disposed partly in channel 76 and partly in continuous path 78. As rotary switch element 74 is rotated and magnet 80 is caused to follow continuous path 78, due to the shape of continuous path 78, magnet 80 is caused also to slide along substantially straight channel 76.
Rotary switch element 74 rotates about an axis 82 defined within teardrop shaped continuous path 78. A substantially circular portion 84 of continuous path 78 defines an area of substantially continuous and consistent distance from axis 82. A tapered, narrowing portion 86 of general v-shape defines an apex 88 of greater distance from axis 82 then portion 84. Accordingly, as a magnet 80 moves into or away from apex 88 in continuous path 78, magnet 80 also moves along channel 76 in switch body 72. As magnet 80 traverses substantially circular portion 84 of continuous path 78 magnet 80 remains at an end 90 of channel 76 so that reed switch 20 is in an open condition. When magnet 80 is near or in apex 88, magnet 80 is at an opposite end 92 of channel 76 such that reed switch 20 is closed. The relationship between a position of magnet 80 and the closed or opened contacts position in that reed switch 20 is illustrated schematically in
Rotary switch element 74 can be coordinated with gas valve 28 such that portion 86 coordinates with the gas valve positioning when gas flow is at a flow condition for igniting. Substantially circular portion 84 of continuous path 78 coordinates with the gas valve in an off position on one side of tapered narrowing portion 86, and with continuously adjustable positions for controlled gas flow between the various desired flame intensities on the other side of tapered narrowing portion 86. Accordingly, magnet 80 is held in position such that switch 20 is open when gas flow is off. Magnet 80 moves toward a position such that switch 20 closes as gas flow is initiated for ignition. Thereafter, when ignition is complete and the flame is adjusted between low and high conditions, magnet 80 is again moved in channel 76 such that switch 20 opens.
Rotary switch element 74 defines a cam track or continuous path 122 somewhat differently shaped than cam track 78. Magnet 80 is disposed partly in channel 76 and partly in cam track 122.
A substantially circular portion 84 is provided in cam track 122 and defines an area of substantially continuous and consistent distance from axis 82. A tapered, narrowing portion 124 of general v-shape defines a path of smaller distance from axis 82 than a distance between axis 82 and circular portion 84. Accordingly, as a magnet 80 moves into or out of portion 124, magnet 80 also moves along channel 76 in switch body 72. As magnet 80 traverses substantially circular portion 84 of cam track 122, magnet 80 remains at an end 92 of channel 76 so that reed switch 20 is in a closed condition. When magnet 80 traverses portion 124, magnet 80 also traverses channel 76, between ends 90 and 92, which changes the position of magnet 80 relative to first and second contacts 52, 54. The relationship between a position of magnet 80 and the closed or opened contacts position in reed switch 20 is illustrated schematically in
Variations and modifications of the foregoing are within the scope of the present invention. It is understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text and/or drawings. All of these different combinations constitute various alternative aspects of the present invention. The embodiments described herein explain the best modes known for practicing the invention and will enable others skilled in the art to utilize the invention. The claims are to be construed to include alternative embodiments to the extent permitted by the prior art.
Various features of the invention are set forth in the following claims.
The present regular United States Patent Application claims the benefits of U.S. Provisional Application Ser. No. 60/817,388, filed on Jun. 29, 2006.
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Number | Date | Country | |
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20080003532 A1 | Jan 2008 | US |
Number | Date | Country | |
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60817388 | Jun 2006 | US |