CN216953168U - Kitchen range panel and kitchen range - Google Patents

Abstract

The utility model provides a kitchen range panel and a kitchen range, wherein the kitchen range panel comprises: a glass panel having one or more first openings therein for receiving the burner; the first heat conducting part is attached to the glass panel around the first opening, and the heat at the position where the heat is concentrated in the glass panel is transferred to the position where the heat is relatively low by utilizing the characteristic that the first heat conducting part is arranged to transfer the heat, so that the temperature difference among different positions in the glass panel is reduced. Because the temperature difference can reduce, consequently, the glass panel also can reduce because of the inhomogeneous probability that bursts that appears of temperature, so the cooking utensils panel that this application provided can prolong the life of product, simultaneously, has improved the safety in utilization of product.

Description

Kitchen range panel and kitchen range

Technical Field

The utility model relates to the technical field of cookers, in particular to a cooker panel and a cooker.

Background

When the existing stove is used, the tempered glass panel near the stove head is heated by flame and is heated more intensely than the edge of the panel, so that the tempered glass panel is heated unevenly and is easy to burst.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art or the related art.

To this end, a first aspect of the utility model provides a cooktop panel.

In a second aspect of the utility model, a cooktop is provided.

In view of the above, according to a first aspect of the present invention, there is provided a cooktop panel comprising: a glass panel having one or more first openings therein for receiving the burners; and the first heat conducting part is attached to the glass panel around the first opening.

The utility model provides a technical scheme has provided a cooking utensils panel, has contained glass panels and the laminating first heat-conducting part that sets up on glass panels in this cooking utensils panel, utilizes the thermal characteristics of the first heat-conducting part transmission that sets up, with the heat transfer to the position department that the heat is relatively lower of the position department of concentrating in the glass panels to reduce the temperature difference between the different positions in the glass panels. Because the temperature difference can reduce, consequently, the glass panel also can reduce because of the inhomogeneous probability that bursts that appears of temperature, so the cooking utensils panel that this application provided can prolong the life of product, simultaneously, has improved the safety in utilization of product.

In addition, consider that the position that the high temperature appears in the cooking utensils panel usually is the kitchen range department, and consequently, the probability that the glass panels appears bursting in the kitchen range department can be higher, consequently, the technical scheme of this application sets up on the glass panels along the laminating of first opening through first heat-conducting part to the probability that the glass panels of further reduction kitchen range department appears bursting, thereby improved the life and the security of cooking utensils panel.

In addition, the cooking utensils panel that this application proposed still has following additional technical feature.

In the above technical solution, a first position of the first heat conducting portion close to the first opening has a first thickness, and a second position of the first heat conducting portion far away from the first opening has a second thickness, wherein the first thickness is greater than the second thickness.

In the technical scheme, the glass panel has high temperature drop at the position of the cooking range, so that the probability of bursting is higher.

In order to reduce the probability of the glass panel bursting at the position of the cooking range, the heat conducting performance of the first heat conducting part at the position of the cooking range needs to be improved, and the first heat conducting part close to the first opening is limited to be thicker so as to increase the speed of conducting heat to other positions at the position of the first opening in the glass panel, thereby reducing the probability of the glass panel bursting at the position of the cooking range to the maximum extent.

In one possible technical solution, the thickness of the first heat conduction portion is gradually reduced toward the periphery with the first opening as a center, that is, the thickness of the first heat conduction portion is uniformly changed, so as to form a smooth curved surface on the first heat conduction portion, thereby providing a better appearance. Meanwhile, the reduction of the heat conduction performance caused by the abrupt change of the thickness can be avoided.

In one possible technical scheme, the thickness of the first heat conducting part is reduced in a step shape towards the periphery by taking the first opening as a center, namely, the thickness of the first heat conducting part is reduced in a step shape.

In any of the above technical solutions, the number of the first openings is plural, the first heat conducting portion has a third position, the third position is located between the plural first openings, and the third position has a third thickness, where the third thickness is greater than the second thickness.

In the technical scheme, the thickness of the first heat conducting part under the area between the cooking holes is limited under the condition that the number of the cooking holes is multiple, and the influence of flame on the area between the cooking holes is larger under the condition that the plurality of cooking holes work, so that the third thickness is larger than the second thickness by limiting, the first heat conducting part can provide enough heat conducting performance, the temperature difference between the third position and other positions cannot be large, and the probability of bursting of the third position is reduced.

In one possible technical solution, in the case that the number of the burner is two, that is, in the case that the number of the first openings is two, the third position is a center of a line connecting the two first openings.

In one possible technical solution, in the case that the number of the burner is three, that is, in the case that the number of the first openings is three, the third position is an outer center of a triangle formed by the three first openings.

In any of the above technical solutions, a thermal conductivity of the first heat conduction portion is greater than a thermal conductivity of the glass panel.

In the technical scheme, the heat transfer speed at different positions on the glass panel is accelerated by limiting the size relation of the heat conductivity coefficient, so that the probability of explosion of the panel of the stove is reduced.

In any of the above technical solutions, the glass panel and the first heat conducting portion are an integrated structure.

In this technical scheme, because first heat conduction portion and glass panels formula structure as an organic whole, consequently, need not to install first heat conduction portion on glass panels, reduced the production procedure of cooking utensils panel, need not to assemble again, the reduction in production cost of being convenient for.

In addition, the integral structure is convenient for reduce the whole thickness of the cooker panel and improve the volume of the product.

In any of the above technical solutions, the method further comprises: and the second heat conduction part is attached to the edge position of the glass panel.

In this technical scheme, glass panels need to cut and obtain the size that needs, simultaneously, also need polish the glass panels after the cutting, and above-mentioned cutting all can cause glass panels's border position to appear artificial microcrack with polishing, and the existence of a large amount of microcracks has aggravated the heating burst of glass panels.

In the technical scheme of this application, set up the second heat-conducting portion through laminating at the border position, utilize the second heat-conducting portion to transmit the heat that border position department gathered to make the temperature of border position department tend to average, reduce the too high problem of local temperature, with this probability that reduces the border position and appear bursting.

In any of the above embodiments, the first thickness is greater than or equal to 1 millimeter.

In the technical scheme, the value range of the thickness of the first heat conducting part is specifically given, and the higher the value of the first thickness is, the better the heat conducting performance of the first heat conducting part is, the lower the probability of the glass panel bursting is, and the minimum value of the first thickness is limited, so that the self-exposure rate of the glass is reduced, and meanwhile, the manufacturing cost of the stove panel is reduced.

In one possible embodiment, the first thickness may be 2 mm.

In any of the above technical solutions, the glass panel has a working surface and a mounting surface, the working surface and the mounting surface are arranged away from each other, and the first heat conduction portion is arranged on the mounting surface and/or the working surface.

In this technical scheme, specifically limited the mounted position of first heat-transfer portion, in this technical scheme, the working face can be understood as the one side towards the user, and the installation face is the one side that deviates from the user, through installing first heat-transfer portion under the one side condition towards the user, can realize setting up the effect of a heat-transfer portion between combustor and glass panels, under this effect, the produced flame of combustor can not direct radiation to glass panels on, correspond, the heat of the accumulational on the glass panels has reduced, therefore, the probability that glass panels explodes certainly can be reduced.

In addition, even if heat accumulation occurs on the glass panel, the accumulated heat can be dispersed due to the existence of the first heat conduction part, so that the probability of spontaneous explosion of the glass panel is reduced.

In the technical scheme, the first heat conducting part is arranged on the installation surface, so that the heat accumulated on the glass panel is dispersed, and meanwhile, the attractiveness of the cooker panel is improved.

In one possible technical scheme, the first heat conducting part is arranged on the working surface and the mounting surface simultaneously, so that the possibility of spontaneous explosion of the glass panel is reduced to the maximum extent.

In any of the above technical solutions, the method further includes: and the heat insulation layer is attached to the mounting surface of the glass panel.

In the technical scheme, the heat insulation layer is arranged right below the glass panel, so that the direct contact between flame and the glass panel can be effectively prevented, the glass panel is burst due to overhigh temperature, and the safety is improved.

In the technical scheme, the heat insulation layer can be a metal heat insulation plate, so that the glass panel is protected by the metal heat insulation plate, and the probability that the glass panel is broken due to impact is reduced.

In any of the above technical solutions, the glass panel further has one or more control areas, and the cooktop panel further includes: and the third heat-conducting part is attached to the glass panel and deviates from one side of the control area.

In this solution, the control area may be understood as a control panel on the glass panel, such as a knob that can be installed on the glass panel, considering that the control area may also have a problem of local over-high temperature under the influence of the flame of the burner, and the above problem may finally cause an abnormality in the control area.

In order to avoid the situation, the third heat conduction part is arranged, and the third heat conduction part is utilized to disperse the heat concentrated in the control area, so that the probability of spontaneous explosion of the control area is reduced, and the service life of the control area is prolonged.

In any of the above embodiments, the control area includes an opening.

In this solution, the control area comprises an opening by definition, so that the knob is mounted on the glass panel by means of this opening.

In the technical scheme, the third heat conduction part is limited to be positioned on one side away from the control area, so that the attractiveness of the cooker panel is improved.

In any of the above technical solutions, the first heat conduction portion is an aluminum foil heat conduction portion.

In this technical scheme, specifically limited the scheme of selecting of first heat-conduction portion, adopted the aluminium foil heat-conduction portion to ensure the life of first heat-conduction portion.

In the above technical solution, the first heat conduction portion, the second heat conduction portion and the third heat conduction portion may all adopt the scheme of the aluminum foil heat conduction portion.

In any of the above technical solutions, the first heat conducting portion includes a plurality of heat conducting sub-portions, and the plurality of heat conducting sub-portions are disposed at intervals.

In this technical scheme, specifically limited first heat-conducting portion, set up through injecing the interval to reduce the volume of first heat-conducting portion, provide the basis for reducing the manufacturing cost of cooking utensils panel.

In the above technical solution, the plurality of heat conducting subsections can surround the first opening in a star shape with the first opening as a center.

According to a second aspect of the utility model, there is provided a cooktop comprising: a cooktop panel as in any one of the above.

In this technical scheme, the technical scheme of this application has provided a cooking utensils, and its cooking utensils panel that contains has contained glass panels and the laminating sets up the first heat-conducting part on glass panels, utilizes the characteristics of the first heat-conducting part heat transfer that sets up, with the heat transfer to the position department that the heat is lower relatively of the position department of concentrating in the glass panels to reduce the temperature difference between the different positions in the glass panels. Because the temperature difference can reduce, consequently, the glass panel also can reduce because of the inhomogeneous probability that bursts that appears of temperature, so the cooking utensils panel that this application provided can prolong the life of product, simultaneously, has improved the safety in utilization of product.

In addition, the position that appears the high temperature in the cooking utensils panel is generally the kitchen range department, and that is to say, the probability that the glass panel appears bursting in the kitchen range department can be higher, consequently, the technical scheme of this application sets up on the glass panel through laminating first heat conduction portion along first opening to the probability that the glass panel that further reduces kitchen range department appears bursting, thereby improved the life and the security of cooking utensils panel.

In the above technical solution, the method further comprises: and the burner is arranged at the first opening.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 shows a schematic structural view of a cooktop panel in an embodiment of the utility model;

FIG. 2 shows a schematic structural view of a glass panel in an embodiment of the utility model;

fig. 3 shows a schematic configuration diagram of the first heat conduction portion in the embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the component names in fig. 1 to 3 is:

102 glass panel, 104 first heat conducting portion.

Detailed Description

So that the manner in which the above recited aspects, features and advantages of the present invention can be understood in detail, a more particular description of the utility model, briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

Cooktop panels and cooktops according to some embodiments of the utility model are described below with reference to fig. 1-3.

As shown in fig. 1, 2 and 3, according to a first aspect of the utility model, the utility model provides a cooktop panel comprising: a glass panel 102, the glass panel 102 having one or more first openings therein for receiving burners; and a first heat-conducting portion 104 attached to the glass panel 102 around the first opening.

The design of this application has provided a cooking utensils panel, has contained glass panels 102 and the laminating sets up the first heat-conducting part 104 on glass panels 102 in this cooking utensils panel, utilizes the characteristics of the first heat-conducting part 104 heat transfer that sets up, with the heat transfer to the position department that the heat is lower relatively of the position department that the heat is comparatively concentrated in glass panels 102 to reduce the temperature difference between the different positions in glass panels 102. Because the temperature difference can be reduced, consequently, the probability that the glass panel 102 will burst because of the inhomogeneous temperature also can reduce, so the cooking utensils panel that this application provided can prolong the life of product, simultaneously, has improved the safety in utilization of product.

In addition, in the cloud images of the temperature field on the glass panel 102, the temperature at the position of the cooking range is higher, and the temperature far away from the position of the cooking range is lower, considering that the position with the overhigh temperature in the panel of the cooking range is generally the cooking range, that is, the probability of the glass panel 102 bursting at the position of the cooking range is higher, therefore, the design of the present application is to attach the first heat conducting part 104 to the glass panel 102 along the first opening, so as to further reduce the probability of the bursting of the glass panel 102 at the position of the cooking range, thereby improving the service life and the safety of the panel of the cooking range.

In one possible design, the first heat conducting portion 104 is a laminated structure having the same area as the glass panel 102 to ensure uniformity of heat distribution throughout the glass panel 102, thereby reducing the chance of the entire glass panel 102 bursting.

Assuming that the overall heating uniformity of the glass panel 102 is 150 ℃, the thermal stress of the glass panel 102 is zero under the temperature field condition obtained through finite element calculation, and the first heat conduction part 104 is arranged, so that the non-uniformity of the temperature of the glass panel 102 is effectively reduced, and the self-explosion rate caused by the thermal stress of the glass panel 102 and the thermal stress of the tempered glass is reduced.

In the above design, a first position of the first heat conduction portion 104 close to the first opening has a first thickness, and a second position far from the first opening has a second thickness, wherein the first thickness is greater than the second thickness.

In this design, the probability of a burst is higher given the large temperature drop of the glass panel 102 at the cooktop location.

In order to reduce the probability of the glass panel 102 bursting at the cooktop location, it is necessary to improve the heat conduction performance of the first heat conduction portion 104 at the cooktop location, and by defining the first heat conduction portion 104 closer to the first opening to be thicker, the speed of heat conduction from the first opening location to other locations in the glass panel 102 is increased, so as to reduce the probability of the glass panel 102 bursting at the cooktop location to the greatest extent.

In one possible design, the thickness of the first heat conduction portion 104 is gradually decreased toward the periphery with the first opening as the center, that is, the thickness of the first heat conduction portion 104 is uniformly changed, so as to form a smooth curved surface on the first heat conduction portion 104, thereby providing a better appearance. Meanwhile, the reduction of the heat conduction performance caused by the abrupt change of the thickness can be avoided.

In one possible design, the thickness of the first heat conducting part 104 is reduced in a step shape around the first opening, that is, the thickness of the first heat conducting part 104 is reduced in a step shape.

In any of the above designs, the number of the first openings is multiple, the first heat conduction portion 104 has a third position located between the multiple first openings, and the third position has a third thickness, wherein the third thickness is greater than the second thickness.

In this design, the thickness of the first heat conduction portion 104 in the area between the cooktops is specifically limited when the number of cooktops is multiple, and considering that the area between the cooktops is more affected by flame when multiple cooktops are operated, the third thickness is larger than the second thickness, so that the first heat conduction portion 104 can provide enough heat conduction performance to ensure that the temperature difference between the third position and other positions is not large, and the possibility of explosion of the third position is reduced.

In one possible design, in the case where the number of the burner ports is two, that is, in the case where the number of the first openings is two, the third position is a center of a line connecting the two first openings.

In one possible design, in the case where the number of burner ports is three, that is, in the case where the number of first openings is three, the third position is the outer center of the triangle formed by the three first openings.

In any of the above designs, the first heat conducting portion 104 has a thermal conductivity greater than that of the glass panel 102.

In the design, the heat transfer speed at different positions on the glass panel 102 is increased by limiting the size relation of the heat conductivity coefficient, so that the burst probability of the cooker panel is reduced.

In any of the above designs, the glass panel 102 and the first heat conducting portion 104 are an integral structure.

In the design, the first heat conducting part 104 and the glass panel 102 are of an integrated structure, so that the first heat conducting part 104 is not required to be installed on the glass panel 102, the production flow of the cooker panel is reduced, the assembly is not required, and the production cost is reduced conveniently.

In addition, the integral structure is convenient for reduce the whole thickness of the cooker panel and improve the volume of the product.

In any of the above designs, further comprising: and a second heat conduction part attached to the edge of the glass panel 102.

In the design, the glass panel 102 is heated and expanded due to the temperature rise, the distribution of the thermal stress field formed by the temperature field is obtained through finite element calculation, the thermal stress value of the edge position of the glass panel 102 is large, the glass panel 102 needs to be cut to obtain a required size, meanwhile, the cut glass panel 102 needs to be polished, artificial microcracks occur at the edge position of the glass panel 102 due to the cutting and polishing, and the thermal explosion of the glass panel 102 is aggravated due to the existence of a large number of microcracks.

In the design of this application, set up the second heat-conducting portion through laminating at the border position, utilize the second heat-conducting portion to transmit the heat that border position department converged to make the temperature of border position department tend to averagely, reduce the too high problem of local temperature, with this reduction border position probability that bursts appears.

In any of the above designs, the first thickness is greater than or equal to 1 millimeter.

In the design, the value range of the thickness of the first heat conducting part 104 is specifically given, and it can be known from the above that the higher the value of the first thickness is, the better the heat conducting performance of the first heat conducting part 104 is, the lower the probability of the glass panel 102 cracking is, and the minimum value of the first thickness is limited, so that the self exposure rate of the glass is reduced, and the manufacturing cost of the cooker panel is reduced.

In one possible design, the first thickness may be 2 mm.

In any of the above designs, the glass panel 102 has a working surface and a mounting surface, the working surface and the mounting surface being disposed apart, and the first heat conduction portion 104 is disposed on the mounting surface and/or the working surface.

In this design, the installation position of the first heat conduction part 104 is specifically defined, in this design, the working surface can be understood as the surface facing the user, and the installation surface is the surface facing away from the user, by installing the first heat conduction part 104 on the surface facing the user, the effect of arranging one heat conduction part between the burner and the glass panel 102 can be realized, under this effect, the flame generated by the burner cannot be directly radiated onto the glass panel 102, correspondingly, the accumulated heat on the glass panel 102 is reduced, and therefore, the probability of spontaneous explosion of the glass panel 102 can be reduced.

In addition, even if heat is accumulated on the glass panel 102, the accumulated heat is dispersed due to the first heat conduction portion 104, so as to reduce the possibility of spontaneous explosion of the glass panel 102.

In the above-described design, by attaching the first heat conduction portion 104 to the attachment surface, the heat accumulated on the glass panel 102 is dispersed, and the appearance of the cooktop panel is improved.

In one possible design, both the working surface and the mounting surface are provided with the first heat transfer portion 104 to minimize the chance of spontaneous explosion of the glass panel 102.

In any of the above designs, further comprising: and a heat insulating layer attached to the mounting surface of the glass panel 102.

In the design, the heat insulation layer is arranged right below the glass panel 102, so that the flame can be effectively prevented from directly contacting with the glass panel 102, the glass panel 102 is burst due to overhigh temperature, and the safety is improved.

In the above design, the thermal insulation layer may be a metal thermal insulation board, so that the glass panel 102 is protected by the metal thermal insulation board, and the possibility of breakage of the glass panel 102 due to impact is reduced.

In any of the above designs, the glass panel 102 further has one or more control zones, and the cooktop panel further comprises: and a third heat-conducting part, which is attached to the glass panel 102 on the side away from the control area.

In this design, the control area is understood to be a control panel on the glass panel 102, such as a knob that can be mounted on the glass panel 102, considering that the control area also has the problem of local temperature excess under the influence of the flame of the burner, which eventually causes an anomaly in the control area.

In order to avoid the situation, the third heat conduction part is arranged, and the heat concentrated in the control area is dispersed by the third heat conduction part, so that the probability of spontaneous explosion of the control area is reduced, and the service life of the control area is prolonged.

In any of the above designs, the control region includes an opening.

In this design, the control area includes an opening by which the knob is mounted on the glass panel 102.

In the design, the third heat conduction part is limited to be positioned on the side away from the control area, so that the aesthetic property of the cooker panel is improved.

In any of the above designs, the first heat conducting portion 104 is an aluminum foil heat conducting portion.

In this design, the selection scheme of the first heat conduction part 104 is specifically defined, and the use of the aluminum foil heat conduction part ensures the service life of the first heat conduction part 104.

In the above design, the first heat conduction portion 104, the second heat conduction portion, and the third heat conduction portion may all adopt an aluminum foil heat conduction portion.

In any of the above designs, the first heat transfer portion 104, the second heat transfer portion, and the third heat transfer portion are an integral structure.

In any of the above designs, the first heat conducting portion 104 includes a plurality of heat conducting sub-portions, and the plurality of heat conducting sub-portions are disposed at intervals.

In the design, the first heat conducting part 104 is specifically defined, and the first heat conducting part 104 is arranged by defining intervals so as to reduce the volume of the first heat conducting part 104, thereby providing a foundation for reducing the manufacturing cost of the cooker panel.

In the above design, the plurality of heat conductive sub-portions may be centered around the first opening in a star shape.

In one possible design, the glass panel 102 is a Tempered glass panel 102, and the Tempered/strengthened glass surface has compressive stress. Also known as tempered glass. And (3) strengthening the glass by adopting a toughening method.

Wherein, the toughened glass belongs to safety glass. The tempered glass is actually prestressed glass, and in order to improve the strength of the glass, a chemical or physical method is usually used to form compressive stress on the surface of the glass, and the glass firstly counteracts surface stress when bearing external force, so that the bearing capacity is improved, and the wind pressure resistance, the cold and hot property, the impact property and the like of the glass are enhanced.

According to a second aspect of the utility model, there is provided a cooktop comprising: a cooktop panel as in any one of the above.

In this design, the design of this application has proposed a cooking utensils, and its cooking utensils panel that contains has contained glass panels 102 and the laminating sets up the first heat-conducting part 104 on glass panels 102, utilizes the characteristics of the first heat-conducting part 104 heat transfer that sets up, with the heat transfer to the position that the heat is lower relatively of the more concentrated position department of heat in glass panels 102 to reduce the temperature difference between the different positions in glass panels 102. Because the temperature difference can be reduced, consequently, the probability that the glass panel 102 will burst because of the inhomogeneous temperature also can reduce, so the cooking utensils panel that this application provided can prolong the life of product, simultaneously, has improved the safety in utilization of product.

In addition, considering that the position of the cooker panel with too high temperature is usually the position of the cooker opening, that is, the probability of the glass panel 102 bursting at the position of the cooker opening is higher, the design of the present application arranges the first heat conducting part 104 on the glass panel 102 along the first opening in an attaching manner, so as to further reduce the probability of the glass panel 102 bursting at the position of the cooker opening, thereby improving the service life and the safety of the cooker panel.

In the above design, the method further comprises: and the burner is arranged at the first opening.

In one possible design, the burner is snapped into the first opening.

In the description of the present invention, the terms "plurality" or "a plurality" refer to two or more, and unless otherwise specifically limited, the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention; the terms "connected," "mounted," "secured," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral connections; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description of the present invention, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In the present invention, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (15)

1. A cooktop panel, comprising:

a glass panel having one or more first openings therein for receiving burners;

and the first heat conduction part is attached to the glass panel around the first opening.

2. The cooktop panel of claim 1, wherein a first location of the first thermally conductive portion proximate the first opening has a first thickness, a second location distal the first opening has a second thickness,

wherein the first thickness is greater than the second thickness.

3. The cooktop panel of claim 2, wherein the first opening is plural in number, the first heat conducting portion has a third position located between the plurality of first openings, the third position has a third thickness,

wherein the third thickness is greater than the second thickness.

4. The cooktop panel of claim 1, wherein the first heat conducting portion has a thermal conductivity greater than a thermal conductivity of the glass panel.

5. The cooktop panel of claim 1, wherein the glass panel and the first heat conducting portion are a unitary structure.

6. The cooktop panel of claim 1, further comprising:

and the second heat conduction part is attached to the edge position of the glass panel.

7. The cooktop panel of claim 2, wherein the first thickness is greater than or equal to 1 millimeter.

8. The cooktop panel according to any one of claims 1 to 7, wherein the glass panel has a working face and a mounting face, the working face and the mounting face being arranged facing away from each other, the first heat conducting portion being arranged on the mounting face and/or the working face.

9. The cooktop panel of claim 8, further comprising:

and the heat insulation layer is attached to the mounting surface of the glass panel.

10. The cooktop panel of claim 8, wherein the glass panel further has one or more control zones, the cooktop panel further comprising: a third heat-conducting part for conducting heat,

the third heat-conducting part is attached to the glass panel and deviates from one side of the control area.

11. The cooktop panel of claim 10, wherein the control region comprises an opening.

12. The cooktop panel of claim 8, wherein the first heat conductor is an aluminum foil heat conductor.

13. The cooktop panel of claim 8, wherein the first heat conducting portion comprises a plurality of heat conducting subsections, the plurality of heat conducting subsections being spaced apart.

14. A cooking utensil, characterized in that includes:

the cooktop panel of any of claims 1 to 13.

15. The cooktop of claim 14, further comprising:

a burner mounted at the first opening.

Images