This disclosure relates generally to the field of cooking and more specifically to a cooking vessel support grate.
Traditionally, one or more grates may be positioned over gas burners of a cooking range. These grates may support a cooking vessel (e.g., a cooking pot) over the flame emitted by the gas burners. The grates may be removable from the cooking range, allowing a user to clean spilled food, spatter, and debris off of the cooking range (e.g., off of a pan positioned on the cooking range). These traditional grates, however, may be deficient.
In a first example, a cooking vessel support grate comprises: a grate with four downward extending legs positioned on opposing corners of the grate, each leg having a lower surface; an upward extending cavity disposed on the lower surface of each of the legs, the upward extending cavity having a non-circular cavity region that extends upward from the lower surface of the respective leg, the upward extending cavity further having an upper cavity region that extends upward from the non-circular cavity region of the respective leg; and an elastic member attached to each of the legs, the elastic member having an upper portion that at least partially fills the cavity of the respective leg, the elastic member further having a lower portion that projects downward from the lower surface of the respective leg and that covers the surface area of the lower surface of the respective leg, the upper portion of the elastic member having a non-circular elastic member region that extends upward from the lower portion of the elastic member, the non-circular elastic member region being shaped to substantially fill the non-circular cavity region of the respective leg to preclude lateral rotation of the elastic member within the cavity of the respective leg, the upper portion of the elastic member further having an upper elastic member region that extends upward from the non-circular elastic member region, the upper elastic member region being shaped to at least partially fill the upper cavity region of the respective leg.
In a second example, a cooking vessel support grate comprises: a grate with at least two downward extending legs, each leg having a lower surface; an upward extending cavity disposed on the lower surface of each of the legs; and an elastic member attached to each of the legs, the elastic member having an upper portion that at least partially fills the cavity of the respective leg, the elastic member further having a lower portion that projects downward from the lower surface of the respective leg and that covers the surface area of the lower surface of the respective leg.
Another example includes any such cooking vessel support grate, wherein the at least two downward extending legs comprises four downward extending legs positioned on opposing corners of the grate.
Another example includes any such cooking vessel support grate, wherein the at least two downward extending legs comprises two downward extending legs positioned on opposing sides of the grate, each leg extending across the lateral expanse of the grate.
Another example includes any such cooking vessel support grate, further comprising an adhesive that bonds the upper portion of the elastic member to the cavity of the respective leg.
Another example includes any such cooking vessel support grate, wherein: the upward extending cavity has a non-circular cavity region that extends upward from the lower surface of the respective leg; and the upper portion of the elastic member has a non-circular elastic member region that extends upward from the lower portion of the elastic member, the non-circular elastic member region being shaped to substantially fill the non-circular cavity region of the respective leg to preclude lateral rotation of the elastic member within the cavity of the respective leg.
Another example includes any such cooking vessel support grate, wherein: the upward extending cavity further has an upper cavity region that extends upward from the non-circular cavity region of the respective leg; and the upper portion of the elastic member further has an upper elastic member region that extends upward from the non-circular elastic member region, the upper elastic member region being shaped to at least partially fill the upper cavity region of the respective leg.
Another example includes any such cooking vessel support grate, wherein the upper elastic member region of the elastic member has circular symmetry.
Another example includes any such cooking vessel support grate, further comprising an adhesive that bonds the upper portion of the elastic member to the cavity of the respective leg, wherein the adhesive fills a space in-between a horizontal outer surface of the upper elastic member region and a horizontal inner wall of the upper cavity region of the respective leg.
Another example includes any such cooking vessel support grate, wherein: the upward extending cavity further has a top cavity region that extends upward from the upper cavity region of the respective leg and also extends upward from the upper elastic member region of the elastic member of the respective leg; and the top cavity region is filled with an adhesive that bonds the upper portion of the elastic member to the cavity of the respective leg.
Another example includes any such cooking vessel support grate, wherein: the adhesive further fills a space in-between a horizontal outer surface of the upper elastic member region and a horizontal inner wall of the upper cavity region of the respective leg; and the adhesive extends within the cavity no further than the non-circular cavity region of the respective leg.
In a third example, a method comprises: providing a grate that has at least two downward extending legs, each leg having a lower surface, the grate further having an upward extending cavity disposed on the lower surface of each of the legs, the upward extending cavity having a non-circular cavity region that extends upward from the lower surface of the respective leg, the upward extending cavity further having an upper cavity region that extends upward from the non-circular cavity region of the respective leg; and attaching an elastic member to each of the legs, the elastic member having an upper portion that at least partially fills the cavity of the respective leg, the elastic member further having a lower portion that projects downward from the lower surface of the respective leg and that covers the surface area of the lower surface of the respective leg, the upper portion of the elastic member having a non-circular elastic member region that extends upward from the lower portion of the elastic member, the non-circular elastic member region being shaped to substantially fill the non-circular cavity region of the respective leg to preclude lateral rotation of the elastic member within the cavity of the respective leg, the upper portion of the elastic member further having an upper elastic member region that extends upward from the non-circular elastic member region, the upper elastic member region being shaped to at least partially fill the upper cavity region of the respective leg.
Another example includes any such method, wherein the at least two downward extending legs comprises four downward extending legs positioned on opposing corners of the grate.
Another example includes any such method, wherein the at least two downward extending legs comprises two downward extending legs positioned on opposing sides of the grate, each leg extending across the lateral expanse of the grate.
Another example includes any such method, wherein attaching the elastic member to each of the legs comprises positioning the upper portion of the elastic member into the cavity of each of the legs.
Another example includes any such method, wherein attaching the elastic member to each of the legs comprises positioning adhesive into the cavity of each of the legs, and then positioning the upper portion of the elastic member into the cavity of each of the legs.
Another example includes any such method, wherein: the upward extending cavity has a non-circular cavity region that extends upward from the lower surface of the respective leg; and the upper portion of the elastic member has a non-circular elastic member region that extends upward from the lower portion of the elastic member, the non-circular elastic member region being shaped to substantially fill the non-circular cavity region of the respective leg to preclude lateral rotation of the elastic member within the cavity of the respective leg.
Another example includes any such method, wherein: the upward extending cavity further has an upper cavity region that extends upward from the non-circular cavity region of the respective leg; and the upper portion of the elastic member further has an upper elastic member region that extends upward from the non-circular elastic member region, the upper elastic member region being shaped to at least partially fill the upper cavity region of the respective leg.
Another example includes any such method, wherein the upper elastic member region of the elastic member has circular symmetry.
In a fourth example, a cooking vessel support grate comprises: a grate with at least two downward extending legs, each leg having a lower surface; an upward extending cavity disposed on the lower surface of each of the legs, the upward extending cavity having a non-circular cavity region that extends upward from the lower surface of the respective leg, the upward extending cavity further having an upper cavity region that extends upward from the non-circular cavity region of the respective leg.
In a fifth example, an elastic member comprises: an upper portion that is configured to at least partially fills a cavity of a respective leg of a cooking vessel support grate; a lower portion that is configured to project downward from a lower surface of the respective leg and that is configured to cover the surface area of the lower surface of the respective leg, the upper portion of the elastic member having a non-circular elastic member region that extends upward from the lower portion of the elastic member, the upper portion of the elastic member further having an upper elastic member region that extends upward from the non-circular elastic member region.
For a more complete understanding of the present disclosure and its features and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which:
Embodiments of the present disclosure are best understood by referring to
Traditionally, one or more grates may be positioned over gas burners of a cooking range. These grates may support a cooking vessel (e.g., a cooking pot) over the flame emitted by the gas burners. The grates may be removable from the cooking range, allowing a user to clean spilled food, spatter, and debris off of the cooking range (e.g., off of a pan positioned on the cooking range). These traditional grates, however, may be deficient. For example, these traditional grates may be likely to cause damage to the cooking range. As such, a user may be required to exercise exceptional care when removing and replacing the grates, so as to avoid marring or scratching the pan of the cooking range.
Some traditional grates may utilize rubber or elastic bumpers to absorb the shock of placing heavy pots on the grate, so as to avoid marring the cooking range (e.g., avoid marring the pan positioned on the cooking range). These traditional rubber or elastic bumpers, however, tend to be small. As such, they do not protect the cooking range from scratches or damage when the grate is moved or removed for cleaning the pan of the cooking range, unless the grate is held perfectly horizontal during the movement. Some larger bumpers have been used with these traditional grates. These larger bumpers tend to accidentally catch on surfaces and dislodge from the grate, causing the cooking range to no longer be protected from damage.
Contrary to these traditional grates and bumpers, the cooking vessel support grate 100 of
The cooking range 1000 may include one or more gas burners 1001 that emit a flame when turned on. The cooking range 1000 may include any number of gas burners 1001. For example, the cooking range 1000 may include 1 gas burner 1001, 2 gas burners 1001, 3 gas burners 1001, 4 gas burners 1001, 5 gas burners 1001, 6 gas burners 1001, or any other number of gas burners 1001.
The cooking range 1000 may further include a pan 10 surrounding the gas burners 1001, causing the gas burners 1001 to be disposed proximal to a bottom portion of the pan 10. The pan 10 may provide a cleanable surface to catch food drippings, food splatters, accidental spills, fluid boiling over from a pot, spilt food, or any combination of the preceding. The pan 10 may be made of stainless steel (e.g., highly polished stainless steel), porcelain, any other cooking material, or any combination of the preceding. The pan 10 may include an upper flange 15 that generally rests on an upper frame of the support structure 1010, and may further include an inner rim 1011 that surrounds an opening (or fitted cavity) 1002 in the support structure 1010.
The cooking range 1000 may also include one or more cooking vessel support grates 100 disposed over and resting on the pan 10. The cooking vessel support grate 100 may be a support structure that supports a cooking vessel (e.g., a cooking pan, a cooking pot, etc.) over one or more of the gas burners 1001, allowing the cooking vessel to be heated by the flames emitted by the gas burners 1001. The cooking vessel support grate 100 may expand over an entire width of the pan 10, allowing it to support cooking vessels over the entire width of the pan 10.
The cooking range 1000 may include any number of cooking vessel support grates 100. For example, the cooking range 1000 may include 1 cooking vessel support grate 100, 2 cooking vessel support grates 100, 3 cooking vessel support grates 100, 4 cooking vessel support grates 100, or any other number of cooking vessel support grates 100. In some examples, the cooking range 1000 may include 1 cooking vessel support grate 100 for each gas burner 1001. In other examples, the cooking range 1000 may include 1 cooking vessel support grate 100 for two (or more) gas burners 1001. In examples where the cooking range 1000 includes multiple cooking vessel support grates 100, the cooking vessel support grates 100 may be positioned adjacent to each other on the pan 10.
The cooking vessel support grate 100 may include an upper surface (or plane) 101 that supports the cooking vessel over one or more of the gas burners 1001. The upper surface 101 may be defined by an expanse of interconnected support members, as is illustrated in
The cooking vessel support grate 100 may further include two or more legs 110 that extend downward from the upper surface 101 (e.g., extend downward from the interconnected support members that define the upper surface 101). When the cooking vessel support grate 100 is positioned on the cooking range 1000, the downward extending legs 110 may rest indirectly on the pan 10, holding the upper surface 101 a desired distance above pan 10 and/or the gas burners 1001. The cooking vessel support grate 100 may include any number of legs 110. For example, as is seen in
As another example, the cooking vessel support grate 100 may include 6 legs 110, with 4 legs 110 positioned on opposing corners of the cooking vessel support grate 100 (as is seen in
As a further example, the cooking vessel support grate 100 may include only 2 legs 110 (e.g., legs 110a and 110b), as is seen in
Each leg 110 of the cooking vessel support grate 100 may rest on a peripheral region 11 of the pan 10, as is illustrated in
As is illustrated in
As is mentioned above, the cooking vessel support grate 100 may further include an elastic member 130 positioned on the lower surface 111 of each leg 120. The elastic member 130 may be a structure or device that provides an elastic cushion to the legs 120 of the cooking vessel support grate 100. This may, in some examples, provide protection to the pan 10. For example, it may allow a user to more easily remove the cooking vessel support grate 100 from the pan 10 (so as to clean the pan 10 and/or the cooking vessel support grate 100) and more easily replace the cooking vessel support grate 100 on the pan 10 (after the pan 10 and/or the cooking vessel support grate 100 has been cleaned). In such an example, the elastic members 130 may provide a cushion that prevents the legs 110 (or any other portion of the cooking vessel support grate 100, such as the interconnected members that make up the upper surface 101) from accidentally contacting the pan 10 and accidentally scratching, marring, or damaging the pan 10. As such, the cooking vessel support grate 100 may be removed and/or replaced without considerable strength, skill, and/or attention that might otherwise be required to avoid such accidental damage.
As another example, the elastic members 130 may provide a cushion that absorbs the energy and/or weight of a cooking vessel. In such an example, a heavy cooking vessel (e.g., a pot) or a full cooking vessel may be dropped on the cooking vessel support grate 100, and this energy may be absorbed by the elastic members 130, preventing damage to the pan 10 (and/or the surrounding frame and cabinetry) from such an impact.
The elastic members 130 may also extend upward into the cavities 120 (and may also be strongly bonded in multiple regions to the cavities 120) in the legs 110, allowing the elastic members 130 to absorb shocks caused by the moving of heavy pots and pans filled with food stuffs, without being deformed, dislodged or rotated, and further allowing the elastic members 130 to prevent the cooking vessel support grate 100 from slipping and marring the pan 10.
The elastic member 130 may be made of any material that provides a cushion. Furthermore, the elastic member 130 may also be made of any material that both provides a cushion and that also is elastic (i.e., the material resumes its normal shape spontaneously after contraction, dilation, or distortion). In a preferred example, the elastic member 130 may be made of silicone, silicone rubber, fluoridated silicone rubber, fluorosilicone rubber, thermo-set resin (e.g., resin soft enough to not scratch polished or satin finished stainless steel, or ceramic-like porcelain finishes on metal), or any combination of the preceding. In another preferred example, the elastic material 130 may be made of the material SE01770T from Chang Horing Rubber Co., LTD. In some examples, the elastic material 130 may be made of a resilient elastic material. Such a resilient elastic material may be a material (e.g., silicone rubber, fluorosilicone rubber, and the like) that is soft enough not to scratch or mar stainless steel, as well as not compress under the load of the cooking vessel support grate 100, cooking vessels, and their contents so that a portion (e.g., a metal portion) of the cooking vessel support grate 100 would contact the pan 10 (e.g., a stainless steel pan 10). Also, such a resilient elastic material may withstand and not degrade from repeated exposure to heat from cooking such as about 150-200° C. or greater, and not undergo compression set, creep, or tear when subjected to repeated compressive and shear stress of at least about 50% or at anticipated loading of the cooking vessel support grate 100, cooking vessels and their contents.
As is illustrated in
To hold the upper portion 131 within the cavity 120, the cooking vessel support grate 100 may include an adhesive 140 disposed within the cavity 120. The adhesive 140 may bond the upper portion 131 to the cavity 120 (e.g., it may bond the upper portion 131 to one or more inner walls of the cavity 120), holding the upper portion 131 within the cavity 120. This bond may prevent the elastic member 130 from being removed from the lower surface 111 of the leg 110. The adhesive 140 may be any type of adhesive that may bond the upper portion 131 to cavity 120. In a preferred example, the adhesive 140 may be a liquid adhesive (e.g., glue).
In some examples, the upper portion 131 may be held within the cavity 120 without the use of an adhesive. For example, the upper portion 131 may be designed to hold itself within the cavity 120. As an example of this, a diameter of the upper portion 131 may be slightly larger than a diameter of the cavity 120. In such an example, the larger diameter of the upper portion 131 may create a snug fit with the smaller diameter of the cavity 120, and the friction created by such a snug fit may hold the upper portion 131 within the cavity 120.
The elastic member 130 may further include a lower portion 132 that extends downward from the upper portion 131. When the elastic member 130 is attached to a leg 110, the lower portion 132 may project downward from the lower surface 111 of the leg 110. This downward projection may provide the elastic cushion to the legs 110 of the cooking vessel support grate 100, preventing the lower surface 111 of the legs 110 from touching the pan 10.
The lower portion 132 may have any size and/or shape that allows it to project downward from the lower surface 111 of the leg 110, so as to provide the elastic cushion to the legs 110. In a preferred example, the lower portion 132 may be sized and/or shaped to extend substantially or completely across the full lateral expanse of the leg 110, while also projecting downward from the lower surface 111 of the leg 110. As an example of this, the lower portion 132 may extend laterally (e.g., in orthogonally opposing directions) over the lower surface 111 of the leg 110 so as to substantially or completely cover the surface area of the lower surface 111.
In a cooking vessel support grate 100 that includes only two legs 110 (e.g., 2 sides 110, as is illustrated in
The lower portion 132 of the elastic member 130 may further be shaped to provide a more secure connection between the pan 10 and the cooking vessel support grate 100. For example, as is illustrated in
It should be understood that the term “non-circular” refers to a geometric shape that deviates from a perfect geometric circle by a sufficient amount to prevent lateral rotation of the elastic member 130 within the cavity and in relation to the leg 110. Examples of a “non-circular” geometric shape include a square, a rectangle, a diamond, a triangle, a crescent shape, or any of such shapes with minor deviations (e.g., rounded corners, fluting, depressions, etc.). A non-circular geometric shape further includes geometric shapes having circular symmetry, but that also deviate from a perfect geometric circle by a sufficient amount to prevent lateral rotation of the elastic member 130 within the cavity and in relation to the leg 110. For example, non-circular geometric shapes include a circular shape with fluting (e.g., peripheral fluting) or depressions (e.g., concave depressions), a gear shape (e.g., having teeth), or a polygonal shape with fluting or depressions (e.g., forming a gear-like shape). In some examples, if the elastic member 130 is made of a material having a low compressive modulus that can deform under rotary shear, the shape of the non-circular elastic member region 133 may need to deviate further from a perfect geometric circle by a sufficient amount in order to be a “non-circular” geometric shape.
In some examples, the shape of the non-circular cavity region 123 may be complimentary to the shape of the non-circular elastic member region 133. That is, the two shapes may fit together. For example, if the non-circular cavity region 123 of the cavity 120 is shaped as a rectangle or substantially shaped as a rectangle (e.g., a rectangle with minor deviations, such as rounded corners, fluting, etc.), the non-circular elastic member region 133 of the elastic member 130 may be shaped as a slightly smaller rectangle or may be substantially shaped as a slightly smaller rectangle, allowing the non-circular elastic member region 133 to fit within the non-circular cavity region 123. In some examples, the two complimentary shapes may assist in preventing the elastic member 130 from rotating laterally within the cavity 120 and in relation to the leg 110.
In some examples, the shape of the non-circular cavity region 123 may not be entirely complimentary to the shape of the non-circular elastic member region 133. However, in such examples, the two shapes may still be sufficiently complementary to prevent the elastic member 130 from rotating laterally within the cavity 120 and in relation to the leg 110. As an example of this, if the non-circular cavity region 123 of the cavity 120 is shaped as a rectangle, the non-circular elastic member region 133 of the elastic member 130 may also be shaped as a slightly smaller rectangle, but the slightly smaller rectangle may include gaps (or flutes) in its shape (i.e., it may be substantially rectangular). In some examples, this deviation from an entirely complementary shape may allow an adhesive 140 to flow into the gaps (or flutes) in the shape of non-circular elastic member region 133 of the elastic member 130. As such, the adhesive 140 may be able to provide a more secure bond between the elastic member 130 and the inner walls of the cavity 120. In some examples, the shape of the non-circular cavity region 123 may correspondingly conform to the shape of the non-circular elastic member region 133. That is, both the non-circular cavity region 123 and the non-circular elastic member region 133 may have the same non-circular shape, and the strength of the adhesive 140 applied between the cavity 120 and the elastic member 130 may be sufficient to prevent the elastic member 130 from rotating in the cavity 120.
In some examples, the non-circular elastic member region 133 may also be shaped (i.e., shaped and sized) to substantially fill the non-circular cavity region 123. Such a substantial filling may refer to a shape (and size) of the non-circular elastic member region 133 that fills a sufficient amount of the volume of the non-circular cavity region 123 to prevent the elastic member 130 from rotating laterally within the cavity 120 and in relation to the leg 110. For example, such a substantial filling may refer to a shape (and size) of the non-circular elastic member region 133 that fills at least 85% (i.e., 85%-100%) of the volume of the non-circular cavity region 123. As another example, such a substantial filling may also refer to a shape (and size) of the non-circular elastic member region 133 that in combination with the adhesive 140 fills at least 90% (i.e., 90%-100%) of the volume of the non-circular cavity region 123. The substantial filling may, in some examples, allow for gaps to be created between the outside surface of the non-circular elastic member region 133 and the inner walls of the non-circular cavity region 123. The adhesive 140 may fill all or a portion of these gaps, thereby creating a stronger bond between the elastic member 130 and the inner walls of the cavity 120.
As is also illustrated in
The upper cavity region 128 of the cavity 120 and the upper elastic member region 138 of the elastic member 130 may each have any shape and/or size that allows the upper elastic member region 138 to extend upward into the upper cavity region 128. For example, one or both of the upper cavity region 128 and the upper elastic member region 138 may have a circular shape or a non-circular shape (examples of which are discussed above). As another example, the upper cavity region 128 and the upper elastic member region 138 may have complementary shapes or partially complementary shapes (examples of both of which are also discussed above). As is illustrated in
The upper elastic member region 138 of the elastic member 130 may be shaped (i.e., shaped and sized) to at least partially fill the upper cavity region 128 of the cavity 120. In some examples, the upper elastic member region 138 of the elastic member 130 may be shaped (i.e., shaped and sized) to substantially fill the upper cavity region 128 of the cavity 120. For example, such a substantial filling may refer to a shape (and size) of the upper elastic member region 138 that fills at least 85% (i.e., 85%-100%) of the volume of the upper cavity region 128. As another example, such a substantial filling may also refer to a shape (and size) of the upper elastic member region 138 that in combination with the adhesive 140 fills at least 90% (i.e., 90%-100%) of the volume of the upper cavity region 128. The substantial filling (or the partial filling) may, in some examples, allow for gaps to be created between the outside surface of the upper elastic member region 138 and one or more inner walls (e.g., horizontal inner walls, top vertical wall) of the upper cavity region 128 of the cavity 120. The adhesive 140 may fill all or a portion of these gaps, thereby creating a stronger bond between the elastic member 130 and the inner walls of the cavity 120. In some examples, the upper elastic member region 138 may be shaped (and sized) to receive a sufficient volume of adhesive 140 to bond the elastic member 130 within the cavity 120 and to the leg 110.
As is further illustrated in
The top cavity region 139 may be filled with the adhesive 140. In some examples, it may be preferable to fill the top cavity region 139 with an amount of adhesive 140 that exceeds the volume of the top cavity region 139. As such, when the upper portion 131 of the elastic member 130 is inserted into the cavity 120, the upper portion 131 may apply pressure to the adhesive 140. To escape this pressure, the adhesive 140 may travel into (and fill) a space (or gap) 141 in-between the horizontal outer surface of the upper elastic member region 138 and a horizontal inner wall of the upper cavity region 128, as is illustrated in
In some examples, the shape of the elastic member 130 may prevent the adhesive 140 from travelling past the top most surface of the non-circular elastic member region 133 of the elastic member 130. As such, the adhesive 140 may be prevented from extending further downward than the non-circular elastic member region 133 of the elastic member 130. In other examples, the adhesive 140 may travel past the top most surface of the non-circular elastic member region 133 of the elastic member 130. For example, the adhesive may travel into (and fill) gaps created between the outside surface of the non-circular elastic member region 133 and inner walls of the non-circular cavity region 123.
As is discussed above, the cavity 120 and the elastic member 130 may have any size. In some examples, it may be preferable for the total depth (or height) of the cavity 120 to be twice the diameter (or width) of the non-circular cavity region 123, or greater. This total depth (or height) of the cavity 120, however, may be limited by the height of the legs 110. Additionally, in some examples it may also be preferable for the diameter (or width) of the non-circular cavity region 123 to be at least half the diameter (or width) of the leg 110. Such dimensions and proportions may provide for a more secure attachment between the elastic member 130 and the cavity 120. Thus, it may provide for a more optimal durability considering the potential for dislodging the elastic member 130 in normal use over time.
Modifications, additions, and/or substitutions may be made to the cooking vessel support grate 100, the components of the cooking vessel support grate 100, and/or the functions of the cooking vessel support grate 100 without departing from the scope of the specification. For example, the cooking vessel support grate 100 may have any dimensions, may include additional components, and/or may not include one or more of the components discussed above.
The method 200 begins at step 205. At step 210, a cooking vessel support grate 100 may be provided. The cooking vessel support grate 100 may be substantially similar (or identical) to the cooking vessel support grate 100 discussed above with regard to
At step 215, one or more elastic members 130 may be provided. The elastic members 130 may be substantially similar (or identical) to the elastic members 130 discussed above with regard to
At step 220, each of the elastic members 130 may be attached to a bottom surface 111 of a respective leg 110 of the cooking vessel support grate 100. The elastic member 130 may be attached to the bottom surface 111 of the respective leg 110 in any manner. For example, a user (via their hands and/or a device) may position the upper portion 131 of the elastic member 130 into the cavity 120 of the leg 110. As another example, a user (via their hands and/or a device) may first position an amount of adhesive 140 into the cavity 120 of the leg 110, and then the user (via their hands and/or a device) may position the upper portion 131 of the elastic member 130 into the cavity 120 of the leg 110. Following attachment of the elastic members 130 to the bottom surfaces 111 of the legs 110, the method may move to step 225, where the method 200 ends.
Modifications, additions, or omissions may be made to method 200. For example, the method 200 may include one or more additional steps. As an example of this, the method may further include positioning the formed cooking vessel support grate 100 onto a cooking range 1000, such as onto a pan 10 of the cooking range 1000. Furthermore, the method 200 may not include one or more of the steps. As an example of this, the method 200 may only include building or forming the cooking vessel support grate 100 (without the elastic member 130), or may only include building or forming the elastic member(s) 130. Additionally, the steps of method 200 may be performed in parallel or in any suitable order.
This specification has been written with reference to various non-limiting and non-exhaustive embodiments or examples. However, it will be recognized by persons having ordinary skill in the art that various substitutions, modifications, or combinations of any of the disclosed embodiments or examples (or portions thereof) may be made within the scope of this specification. Thus, it is contemplated and understood that this specification supports additional embodiments or examples not expressly set forth in this specification. Such embodiments or examples may be obtained, for example, by combining, modifying, reorganizing, or removing any of the disclosed steps, components, elements, features, aspects, characteristics, limitations, and the like, of the various non-limiting and non-exhaustive embodiments or examples described in this specification.
This application claims priority to U.S. Provisional Patent Application No. 62/607,146 filed on Dec. 18, 2017, the entirety of which is incorporated herein by reference.
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Examiner's Report dated Nov. 5, 2020 issued in connection with corresponding Canadian Patent Application No. 3027906. |
Number | Date | Country | |
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20190226684 A1 | Jul 2019 | US |
Number | Date | Country | |
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62607146 | Dec 2017 | US |