Gas stove
1. A gas burner, characterized in that it comprises:
a panel;
the heat preservation body is provided with a first cavity with an opening at the upper part and is arranged on the bearing surface of the panel;
the combustor is accommodated in the first cavity, and the periphery of the combustor is wrapped by the heat insulator.
2. The gas stove of claim 1, wherein the heat insulator comprises a bottom wall and a side wall surrounding the bottom wall, the side wall and the bottom wall form the first cavity, the bottom wall supports the bottom surface of the burner, the side wall surrounds the burner, and a height of the side wall in a direction perpendicular to the bottom wall is greater than or equal to a height of the burner.
3. The gas stove of claim 2, wherein the sidewall is provided with a notch, the notch is communicated with the first cavity, the burner comprises a combustion part and a gas mixing pipe communicated with the combustion part, the combustion part is accommodated in the first cavity, and the gas mixing pipe passes through the notch and extends to the outer side of the heat insulation body.
4. The gas stove of claim 3, wherein the heat insulator is further provided with a second cavity, and the second cavity surrounds the first cavity;
the gas stove further comprises a wok stand, wherein the wok stand is arranged in the second cavity and is framed on the peripheral side of the combustion part.
5. The gas range of claim 4, wherein the pot holder comprises a frame and a plurality of support arms spaced apart from the frame, the frame is disposed around the combustion portion, and the support arms extend out of the heat retaining member to support a pot disposed on the burner.
6. The gas burner of claim 1, further comprising a gas delivery assembly disposed on the bearing surface of the panel for providing gas to the burner.
7. The gas range of claim 6, wherein the burner is detachably connected to the gas delivery assembly.
8. The gas stove of claim 7, wherein the burner comprises a combustion part and a gas mixing pipe communicated with the combustion part, the combustion part is accommodated in the first cavity, and one end of the gas mixing pipe, which is not communicated with the combustion part, is detachably connected to the gas conveying assembly.
9. The gas burner of claim 6, further comprising a holder, wherein the heat insulator is connected to the holder, and wherein the holder is further detachably connected to the gas delivery assembly.
10. The gas stove of claim 1, wherein the heat insulator is made of mica sheets, glass fibers or refractory bricks.
Background
In order to improve the energy efficiency of a gas stove, a circle of heat gathering device is added around a distributor of a burner, but because domestic burners mostly adopt an atmospheric burner with air entering from the lower part, a circle of heat gathering device is added around the distributor of the burner above a table top, only part of the burner can be wrapped, and the heat of the burner below the table top is dissipated inside a stove.
Disclosure of Invention
The application mainly provides a gas stove to solve the problem that the heat of gas stove overflows and loses greatly, and then leads to energy utilization to hang down.
In order to solve the technical problem, the application adopts a technical scheme that: a gas range is provided. The gas range includes: a panel; the heat preservation body is provided with a first cavity with an opening at the upper part and is arranged on the bearing surface of the panel; the combustor is accommodated in the first cavity, and the periphery of the combustor is wrapped by the heat insulator.
In some embodiments, the insulation body includes a bottom wall and a side wall surrounding the bottom wall, the side wall and the bottom wall form the first cavity, the bottom wall supports the bottom surface of the burner, and the side wall surrounds the burner, wherein the height of the side wall along a direction perpendicular to the bottom wall is greater than or equal to the height of the burner.
In some embodiments, the sidewall is provided with a notch, the notch is communicated with the first cavity, the burner comprises a combustion part and a gas mixing pipe communicated with the combustion part, the combustion part is accommodated in the first cavity, and the gas mixing pipe passes through the notch and extends to the outer side of the heat insulation body.
In some embodiments, the heat insulator is further provided with a second cavity, and the second cavity surrounds the first cavity;
the gas stove further comprises a wok stand, wherein the wok stand is arranged in the second cavity and is framed on the peripheral side of the combustion part.
In some embodiments, the pot frame includes a frame body and a plurality of support arms spaced apart from the frame body, the frame body is disposed around the combustion portion, and the support arms extend out of the heat retaining body and are configured to support a pot disposed on the burner.
In some embodiments, the gas stove further comprises a gas delivery assembly disposed on the bearing surface of the panel for providing gas to the burner.
In some embodiments, the burner is removably coupled to the gas delivery assembly.
In some embodiments, the burner includes a combustion portion and a gas mixing pipe communicated with the combustion portion, the combustion portion is accommodated in the first cavity, and one end of the gas mixing pipe, which is not communicated with the combustion portion, is detachably connected to the gas conveying assembly.
In some embodiments, the gas burner further comprises a retainer, the insulator being coupled to the retainer, the retainer being further removably coupled to the gas delivery assembly.
In some embodiments, the insulation is made of mica sheets, glass fibers or refractory bricks.
The beneficial effect of this application is: being different from the situation of the prior art, the application discloses a gas stove. Through generating heat wholly with integrated one of combustor for the combustor becomes the object of generating heat that can be gathered together, and will set up the combustor holding on the bearing surface of panel in the first cavity of insulator, and the combustor is wrapped up by the insulator all around, therefore the combustor can be gathered together by the insulator from the heat that outwards spills over all around, reduce the heat and spill over the loss, and can be with the uncovered working space of heat transfer to combustor and combustor top that gathers together, with the heating efficiency of effectively promoting the combustor, and can improve energy utilization.
Drawings
In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts, wherein:
FIG. 1 is a schematic structural view of an embodiment of a gas range provided by the present application;
fig. 2 is a schematic sectional view of the gas range of fig. 1;
FIG. 3 is a schematic view of the gas range of FIG. 1 with the face plate and the burner removed;
fig. 4 is a schematic structural view of the gas range of fig. 1 with a burner removed;
FIG. 5 is a schematic view of the gas burner of FIG. 4 with the ignition needle assembly removed;
fig. 6 is a schematic view showing the construction of a gas delivery assembly in the gas range of fig. 1;
fig. 7 is a schematic view illustrating a first gas mixing chamber of a burner of the gas range of fig. 1 when it is operated alone;
FIG. 8 is a schematic view of the second mixing chamber of the burner of FIG. 7 operating alone;
fig. 9 is a schematic structural view illustrating a burner coupled to a nozzle holder in the gas range of fig. 1;
FIG. 10 is a schematic view of the burner of FIG. 9 shown separated from the nozzle carrier;
fig. 11 is a structural view illustrating the positions of a burner, a gas delivery assembly, an air supply member and an ignition needle assembly in the gas range of fig. 1;
fig. 12 is a schematic structural view illustrating a pot holder and a fixing member in the gas range of fig. 1;
FIG. 13 is a schematic view of the pan frame of FIG. 12 shown separated from the fixing members;
fig. 14 is an exploded view of the heat-retaining box, burner, pot holder and gas delivery assembly of the gas range of fig. 1;
fig. 15 is a schematic view of a connection structure of the firing pin assembly and the gas delivery assembly in the gas range of fig. 1;
FIG. 16 is a schematic view of the firing pin assembly of FIG. 4 in a first position;
FIG. 17 is a schematic view of the firing pin assembly of FIG. 16 in a second position.
Detailed Description
The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
The terms "first", "second" and "third" in the embodiments of the present application are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," or "third" may explicitly or implicitly include at least one of the feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless explicitly specifically limited otherwise. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.
Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.
Referring to fig. 1 to 4, fig. 1 is a schematic structural view of an embodiment of a gas cooker provided by the present invention, fig. 2 is a schematic sectional structural view of the gas cooker shown in fig. 1, fig. 3 is a schematic structural view of the gas cooker shown in fig. 1 with a panel and a burner on the panel removed, and fig. 4 is a schematic structural view of the gas cooker shown in fig. 1 with the gas cooker removed.
The gas range 100 includes a case 10, a panel 20, a gas delivery assembly 30, a burner 40, an air supply member 50, an ignition pin assembly 60, and a heat-insulating case 70. Wherein, the panel 20 is covered on the housing 10 to form a table top of the gas range 100; the gas delivery assembly 30, the burner 40 and the air supply member 50 are disposed on the bearing surface 21 of the panel 20, the gas delivery assembly 30 is communicated with the burner 40 to provide gas to the burner 40, and the air supply member 50 provides air to the burner 40 to be premixed with the gas; an ignition pin assembly 60 is disposed on the gas delivery assembly 30 to ignite the burner 40; further, the heat-insulating box 70 is disposed on the bearing surface 21 of the panel 20, and the burner 40 is also supported in the heat-insulating box 70 to recycle heat overflowing from the burner 40.
As shown in fig. 2 and 3, the panel 20 is covered on the casing 10, and the panel 20 and the casing 10 cooperate to form an accommodating space 12, and the accommodating space 12 can accommodate a pipeline 81, a regulating valve 82, a controller 83 and other elements which are communicated with the gas delivery assembly 30 and deliver gas to the gas delivery assembly 30.
The panel 20 may be a glass panel, a stainless steel panel or a marble panel, etc., and further has a bearing surface 21 that is easy to clean, facilitating removal of oil stains, etc. after use. Wherein, a side surface of the panel 20 facing away from the housing 10 is a bearing surface 21, and the bearing surface 21 is substantially a plane.
Referring to fig. 1 and 2, the gas delivery assembly 30 is fixedly disposed on the bearing surface 21 of the panel 20, wherein the gas delivery assembly 30 can be completely disposed on the bearing surface 21, and further, the gas delivery opening of the gas delivery assembly 30 is higher than the bearing surface 21 along a direction perpendicular to the bearing surface 21, for example, the gas delivery assembly 30 is fixed on the bearing surface 21 by a fastener such as a screw or a pin, or the gas delivery assembly 30 is fixedly disposed on the bearing surface 21 by a snap-fit connection.
In this embodiment, as shown in fig. 2, the panel 20 is provided with a mounting opening 22, the gas delivery assembly 30 includes a nozzle holder 32 and a nozzle 34, the nozzle 34 is fixed on the nozzle holder 32 and is higher than the bearing surface 21 along the vertical direction, the nozzle holder 32 is disposed through the mounting opening 22, and a pipeline 81 is connected to a side of the nozzle holder 32 facing the housing 10.
The nozzle 34 has a nozzle opening, i.e. a gas delivery opening of the gas delivery assembly 30, the nozzle opening of the nozzle 34 is higher than the bearing surface 21, and the conduit 81 guides the gas towards the nozzle 34 and supplies the gas to the burner 40 via the nozzle opening of the nozzle 34.
The number of the nozzles 34 is at least one, wherein a plurality of the nozzles 34 can supply gas to an equal number of the burners 40, and a plurality of the nozzles 34 can also supply gas to the same burner 40, which is not particularly limited in the present application.
Optionally, the gas delivery assembly 30 includes a nozzle 34, and the nozzle 34 correspondingly provides gas to a burner 40. Alternatively, the gas delivery assembly 30 includes two or three nozzles 34, and each nozzle 34 provides gas to a different burner 40. Alternatively, the gas delivery assembly 30 includes two or three nozzles 34 of equal number, the burner 40 includes the same number of gas mixing pipes 43, and each nozzle 34 injects gas into a corresponding gas mixing pipe 43 to provide gas to the burner 40.
As shown in fig. 2 and 6, fig. 6 is a schematic view showing a structure of a gas delivery assembly in the gas range of fig. 1. The nozzle holder 32 includes a holder body 320 and an air guide pillar 322 disposed on the holder body 320, wherein the holder body 320 is disposed at the mounting opening 22, the nozzle 34 is connected to one end of the air guide pillar 322, the spraying direction of the nozzle 34 is parallel to the bearing surface 21, and the pipeline 81 is connected to the other end of the air guide pillar 322.
Further, the gas transmission assembly 30 further includes a fixing member 33, and the fixing member 33 is connected to the base body 320 and covers the mounting opening 22 to prevent oil and the like from entering the accommodating space 12 on one side of the panel 20 through the mounting opening 22. Alternatively, as shown in fig. 4, the gas delivery assembly 30 further includes a support 328, and the support 328 is detachably connected to the base 320 and covers the mounting opening 22.
In other embodiments, the gas delivery assembly 30 may also be a gas pipe or nozzle or the like disposed on the bearing surface 21, which is not limited in this application.
Referring to fig. 1 and 2, the burner 40 is disposed on the bearing surface 21 of the panel 20, the burner 40 may be fixedly disposed on the bearing surface 21 of the panel 20, or the burner 40 may be detachably disposed on the bearing surface 21 of the panel 20.
For example, the burner 40 is fixedly disposed on the bearing surface 21 by welding, bonding, or the like, or the burner 40 is detachably disposed on the bearing surface 21 by screws, pins, or snaps, or the like. Wherein the burner 40 may be connected to the panel 20 or the gas delivery assembly 30.
In the present embodiment, as shown in fig. 2, the burner 40 includes a combustion portion 41 and a gas-mixed pipe 43 communicating with the combustion portion 41. The combustion part 41 includes a gas mixing chamber 410 connected to the gas mixing pipe 43, and a fire cover 413 covering the gas mixing chamber 410, the fire cover 413 is provided with a plurality of fire outlets, and the premixed gas in the gas mixing chamber 410 is discharged through the fire outlets and combusted.
Optionally, the number of the air mixing cavity 410 is one, the number of the air mixing pipe 43 is one, and the air mixing pipe 43 is communicated with the air mixing cavity 410.
Alternatively, the number of the air mixing cavities 410 is multiple, for example, two or three, and the like, the air mixing pipe 43 is one, and the air mixing cavities 410 are communicated, so that the air mixing pipe 43 is communicated with the air mixing cavities 410.
Optionally, the number of the air mixing cavities 410 is multiple and isolated from each other, and the number of the air mixing pipes 43 is the same as the number of the air mixing cavities 410 and is communicated with each air mixing cavity 410 in a one-to-one correspondence manner.
In this embodiment, referring to fig. 2 and 7, the air mixing chamber 410 includes a first air mixing chamber 411 and a second air mixing chamber 412, the second air mixing chamber 412 is disposed around the first air mixing chamber 411 and isolated from each other, that is, the first air mixing chamber 411 and the second air mixing chamber 412 are independent from each other and not communicated, the air mixing pipe 43 includes a first air mixing pipe 431 and a second air mixing pipe 432, the first air mixing pipe 431 is communicated with the first air mixing chamber 411, and the second air mixing pipe 432 is communicated with the second air mixing chamber 412.
The gas delivery assembly 30 is disposed on the bearing surface 21 of the panel 20 and is located at an end of the gas mixing pipe 43 not connected to the combustion portion 41 for independently providing gas to the first gas mixing pipe 431 and the second gas mixing pipe 432, respectively.
Through the first air mixing cavity 411 and the second air mixing cavity 412 which are arranged in the combustion part 41 and are separated from each other, the first air mixing cavity 411 is independently communicated with the first air mixing pipe 431, the second air mixing cavity 412 is independently communicated with the second air mixing pipe 432, and the first air mixing cavity 411 and the second air mixing cavity 412 are not interfered with each other, so that the first air mixing cavity 411 and the second air mixing cavity 412 can independently provide different combustion areas, and the combustor 40 can provide three combustion areas for users to select. For example, as shown in fig. 7, the user can independently use the combustion area of the first air-mixing chamber 411 for cooking; or as shown in fig. 8, the user can independently use the combustion area of the second air-mixing chamber 412 for cooking; or in conjunction with fig. 7 and 8, the user cooks using the combined combustion area of the first air-mixing chamber 411 and the second air-mixing chamber 412, so that it is possible to more adapt to the user's requirement for the diversity of the combustion area when cooking.
The gas delivery assembly 30 independently provides gas to the first gas mixing pipe 431 and the second gas mixing pipe 432, and then the flow rate of the gas provided to the first gas mixing pipe 431 and the second gas mixing pipe 432 by the gas delivery assembly 30 can be changed, so that the flame temperature levels of the combustion areas of the first gas mixing chamber 411 and the second gas mixing chamber 412 can be independently regulated and controlled, and a user can independently select the flame temperature levels of different combustion areas when using the gas delivery assembly.
For example, when the user uses only the combustion area of the first air-mixing chamber 411, the temperature level of the flame provided by the first air-mixing chamber 411 can be adjusted by adjusting the amount of the gas flow supplied thereto; when the user only uses the combustion area of the second gas mixing cavity 412, the temperature level of the flame provided by the user can be adjusted by adjusting the gas flow supplied to the second gas mixing cavity 412; when the user uses the combustion areas of the first and second air mixing chambers 411 and 412 at the same time, the temperature levels of flames provided by the first and second air mixing chambers 411 and 412 may be different or the same.
Therefore, the gas range 100 provided by the embodiment can provide different combustion areas, and the flame temperature levels of the different combustion areas can be independently selected, so that the gas range can be more suitable for the diversity of cooking conditions required by users, and further more ideal cooking efficiency can be realized.
Referring to fig. 1, 2, 4 and 5 in combination, fig. 4 is a schematic structural view of the gas range shown in fig. 1 with the burner removed, and fig. 5 is a schematic structural view of the gas range shown in fig. 4 with the ignition needle assembly further removed.
In this embodiment, the burner 40 is detachably disposed on the bearing surface 21 of the panel 20 and is removable from the panel 20 to facilitate cleaning of the panel 20. Burner 40 is removably coupled to panel 20 and/or gas delivery assembly 30.
Alternatively, the burner 40 is arranged on the bearing surface 21 by means of a snap fit, for example, the burner 41 and/or the gas mixing tube 43 is arranged on the bearing surface 21 by means of a snap fit and connected to the panel 20 and/or the gas delivery assembly 30. For example, the burning portion 41 is provided with a bayonet or a bayonet, and the like, and the carrying surface 21 of the panel 20 is correspondingly provided with a bayonet or a bayonet, and the bayonet are clamped, so that the burning portion 41 is provided on the carrying surface 21, and the burner 40 can be prevented from moving relative to the carrying surface 21 when in use.
Alternatively, the end of the air mixing pipe 43, which is not connected to the combustion part 41, may be detachably connected to the gas conveying assembly 30 or the panel 20, the air mixing pipe 43 may be connected to the gas conveying assembly 30 or the panel 20 by a fastener such as a screw or a pin, and the air mixing pipe 43 may also be connected to the gas conveying assembly 30 or the panel 20 by a snap-fit manner. For example, the end of the air-fuel mixture pipe 43 not connected to the combustion part 41 is detachably connected to the nozzle holder 32. For example, the end of the air mixing pipe 43 not connected to the combustion part 41 is provided with a connecting plate, and the connecting plate is provided with a through hole for inserting a screw, and the screw detachably connects the connecting plate to the gas transmission assembly 30.
In this embodiment, referring to fig. 9 and 10, fig. 9 is a schematic structural view illustrating a connection between a burner and a nozzle holder in the gas range shown in fig. 1, and fig. 10 is a schematic structural view illustrating a separation between the burner and the nozzle holder shown in fig. 9. The burner 40 is removably attached to the gas delivery assembly 30 for secure placement on the bearing surface 21 of the panel 20. By releasing the connection between the burner 40 and the gas delivery assembly 30, the burner 40 can be removed from the bearing surface 21, so as to reduce the dead angle of cleaning the bearing surface 21 to the maximum extent, facilitate the cleaning of the bearing surface 21 by the user, and reduce the difficulty of cleaning.
The combustion section 41 and/or the gas mixing pipe 43 are detachably connected to the gas delivery assembly 30. For example, the combustion part 41 is detachably attached to the nozzle holder 32 on the side facing the nozzle holder 32, and the air-fuel mixture pipes 43 are not attached to the nozzle holder 32 and are independent from each other. For example, the nozzle holder 32 is provided with a bayonet, the outside of the combustion part 41 is provided with a bayonet, the bayonet and the bayonet are engaged, and the air-fuel mixture pipe 43 is not engaged with the nozzle holder 32. Or, one end of the air mixing pipe 43 is detachably connected to the nozzle holder 32, for example, one end of the air mixing pipe 43 is clamped with the nozzle holder 32; alternatively, both the combustion section 41 and the air-fuel mixture pipe 43 are connected to the nozzle holder 32, and for example, both the combustion section 41 and the air-fuel mixture pipe 43 are engaged with the nozzle holder 32.
In this embodiment, as shown in fig. 9 and 10, the gas mixing pipe 43 is connected to the gas conveying assembly 30 by clamping to be fixedly placed on the bearing surface 21 of the panel 20. In other words, the burner 41 rests on the bearing surface 21 and is not connected to the panel 20, and the gas mixing pipe 43 is connected to the gas delivery assembly 30 by means of a snap fit, so as to facilitate the removal of the burner 40 from the panel 20, and to facilitate the cleaning of the bearing surface 21 of the panel 20.
Specifically, one end of the air-mixing pipe 43, which is not connected to the combustion part 41, is clamped to the nozzle holder 32, and the combustion part 41 is placed on the bearing surface 21 of the panel 20. Alternatively, one end of the air mixing tube 43 can be clamped on the fixing member 33 or the supporting member 328.
In this embodiment, the end of the air mixing pipe 43 not connected to the combustion portion 41 is provided with a clamping interface 433 and a clamping portion 434, and the nozzle 34 is disposed in the air mixing pipe 43 through the clamping interface 433 to communicate with the air mixing pipe 43 and provide the air mixing pipe 43 with the gas, so that all the provided gas can be led into the air mixing pipe 43; the nozzle holder 32 is provided with a clamping groove 324, and the clamping portion 434 is disposed in the clamping groove 324, i.e. the clamping portion 434 is clamped with the clamping groove 324.
Optionally, one end of the air mixing pipe 43, which is not connected to the combustion portion 41, is provided with a clamping port 433 and a clamping groove 324, the nozzle holder 32 is provided with a clamping portion 434, the clamping groove 324 is clamped with the clamping portion 434, and then one end of the air mixing pipe 43 is clamped on the nozzle holder 32.
Referring to fig. 2, 10 and 11, fig. 11 is a schematic view illustrating a position structure of a burner, a gas delivery assembly, an air supply member and an ignition pin assembly in the gas range of fig. 1. The air mixing pipe 43 is a straight pipe section, the air mixing pipe 43 comprises a premixing section 435 and an air collecting section 436 which are communicated, a gas supply port of the gas conveying assembly 30 is located at the air collecting section 436 and used for spraying gas to the premixing section 435, an air outlet of the air supply element 50 faces the air collecting section 436, the pipe diameter of the air collecting section 436 is larger than that of the premixing section 435, then the gas and the air start to be premixed in the premixing section 435, and the premixed gas and air enter the air mixing cavity 410.
The wind gathering section 436 has a larger pipe diameter than the premixing section 435 so as to gather the air supplied from the air supply 50 and guide the air to the premixing section 435, thereby preventing the air supplied from the air supply 50 from overflowing the air mixing pipe 43 to improve the wind intake efficiency.
The air collecting section 436 is a tapered tube, the small end of the tapered tube is connected to the premixing section 435, the large end of the tapered tube faces the air supplying part 50, and the diameter of the large end of the tapered tube is greater than or equal to the size of the air outlet of the air supplying part 50, so as to prevent the air provided by the air supplying part 50 from overflowing the air mixing tube 43, thereby improving the air intake efficiency.
Optionally, the wind collecting section 436 may also be trumpet-shaped, which is not specifically limited in this application.
The wind collecting section 436 is provided with a clamping port 433, the outer side wall of the wind collecting section 436 is provided with a clamping portion 434, the air guiding column 322 penetrates through the clamping port 433 to enter the wind collecting section 436, the nozzle 34 is connected to one end of the air guiding column 322, the nozzle 34 is arranged in the wind collecting section 436 through the clamping port 433, the spraying direction of the nozzle 34 faces the premixing section 435, so that all gas provided by the nozzle 34 can be led into the premixing section 435, and gas leakage is avoided.
Referring to fig. 10, 12 and 13 in combination, fig. 12 is a schematic structural view illustrating the connection of a pot holder and a fixing member in the gas range of fig. 1, and fig. 13 is a schematic structural view illustrating the separation of the pot holder and the fixing member of fig. 12.
In an embodiment, the gas range 100 may further include a pot holder 84, the pot holder 84 is placed on the bearing surface 21 of the panel 20 and is framed around the burner 40 to support a pot above the combustion portion 41, and the pot holder 84 is detachably connected to the gas delivery assembly 30, and the burner 40 is detachably connected to the gas delivery assembly 30, so that the pot holder 84 and the burner 40 can be relatively fixed, the pot holder 84 is prevented from moving, and the pot can be better supported for the user to use.
The wok stand 84 is connected with the gas transmission assembly 30 in a clamping mode so as to be convenient for quickly disassembling or assembling the wok stand 84. One side of the pot frame 84 facing the gas transmission assembly 30 is provided with a first buckling position 840, the gas transmission assembly 30 is provided with a second buckling position 301, and the first buckling position 840 is clamped with the second buckling position 301. The first buckling position 840 and the second buckling position 301 are respectively one of a clamping column or a bayonet.
Specifically, the nozzle holder 32 is provided with a second fastening position 301, or the fixing member 33 is provided with the second fastening position 301, or the supporting member 328 is provided with the second fastening position 301.
Referring again to fig. 12 and 13, in another embodiment, the gas range 100 further includes a pot holder 84, the pot holder 84 rests on the bearing surface 21 of the panel 20, the burner 40 is fixed on the pot holder 84 and is detachably connected to the gas delivery assembly 30 through the pot holder 84, i.e., the burner 40 is indirectly detachably connected to the gas delivery assembly 30 through the pot holder 84, and the pot holder 84 is detachably connected to the nozzle holder 32, the fixing member 33, or the supporting member 328. In other words, the wok stand 84 and burner 40 can be removed from the bearing surface 21 of the panel 20 by disassembling the connection relationship of the wok stand 84 and the gas delivery assembly 30 to facilitate cleaning of the panel 20.
Referring to fig. 14, fig. 14 is an exploded view of the heat-insulating case, the burner, the pot holder and the gas delivery assembly of the gas range of fig. 1.
In another embodiment, the gas range 100 may further include a heat insulation box 70, the heat insulation box 70 is placed on the panel 20, the burner 40 is accommodated in the heat insulation box 70 to recycle heat overflowing from the burner 40, so as to improve heat utilization efficiency, and the heat insulation box 70 and the burner 40 are detachably connected to the gas transmission assembly 30, for example, by fastening or snapping. Wherein, the burner 40 is detachably connected with the nozzle holder 32, and the heat-insulating box 70 is detachably connected with the nozzle holder 32, the fixing member 33 or the supporting member 328.
The heat preservation box 70 is provided with a first cavity 71, a notch 701 is formed in the side wall, facing the gas conveying assembly 30, of the heat preservation box 70, the notch 701 is communicated with the first cavity 71, the combustion part 41 is accommodated in the first cavity 71, and the gas mixing pipe 43 penetrates through the notch 701 and is connected with the gas conveying assembly 30 in a clamping mode. Specifically, one end of the air mixing pipe 43 is clamped with the nozzle holder 32, a first buckling position 840 is arranged on one side of the heat preservation box 70 facing the nozzle holder 32, a second buckling position 301 is arranged on the fixing member 33, and the first buckling position 840 is clamped with the second buckling position 301.
The heat preservation box 70 is further provided with a second cavity 72, the second cavity 72 is surrounded on the first cavity 71, the gas stove 100 further comprises a pot frame 84, the pot frame 84 is arranged in the second cavity 72 and is framed on the periphery of the combustion part 41 to support a pot above the combustion part 41.
With continued reference to fig. 14, in yet another embodiment, the gas range 100 may further include a heat-insulating box 70, the heat-insulating box 70 is placed on the bearing surface 21 of the panel 20, the burner 40 is accommodated in the heat-insulating box 70 and detachably connected to the gas delivery assembly 30 through the heat-insulating box 70, that is, the burner 40 is indirectly detachably connected to the gas delivery assembly 30 through the heat-insulating box 70, and the heat-insulating box 70 may be detachably connected to the nozzle holder 32, the fixing member 33 or the supporting member 328. In other words, the heat-retaining box 70 and the burner 40 can be removed from the bearing surface 21 of the panel 20 by disassembling the connection relationship of the heat-retaining box 70 with the gas delivery assembly 30.
Referring to fig. 2, 9 and 11, the air supply unit 50 is disposed on the bearing surface 21 of the panel 20 and is located at an end of the air mixing pipe 43 not connected to the combustion portion 41 for supplying air into the air mixing pipe 43. The air supply unit 50 may be a fan or a high pressure air pump, or an air pipe connected to the high pressure air pump or the fan.
The air supply 50 may be disposed on the panel 20 or the gas delivery assembly 30, for example, the air supply 50 is fixed to the bearing surface 21 of the panel 20 or the gas delivery assembly 30, or the air supply 50 is detachably connected to the bearing surface 21 of the panel 20 or the gas delivery assembly 30.
By providing the air supply member 50 to actively blow air into the burner 40, and disposing the burner 40, the gas delivery assembly 30 and the air supply member 50 on the bearing surface 21 of the panel 20, the air supply member 50 can be entirely derived from the space on the side of the bearing surface 21, and the limitation of the air supply amount caused by disposing the air supply member 50 in the accommodating space 12 formed by the housing 10 and the panel 20 can be avoided, so that the burner 40 can obtain a sufficient air supply amount, and the purpose of matching the sufficient air supply amount even if the burner 40 uses a large fire force is achieved.
Further, due to the existence of the air supply member 50, compared to the conventional gas stove, the air inlet and the air outlet of the gas stove 100 provided by the present application are both on the panel 20, i.e. there is no need to provide an air inlet below the panel 20 or on the side wall of the housing 10, and the air inlets of the conventional gas stove are more disposed on the side wall of the housing 10, so the panel surface of the conventional gas stove must be higher than the upper surface of the cooking bench, and the panel surface and the upper surface of the cooking bench form a pure plane when the gas stove is embedded into the cooking bench, and the bearing surface 21 and the upper surface of the cooking bench form a pure plane when the gas stove 100 provided by the present application is embedded into the cooking bench because there is no need to prevent the air inlets from being blocked, so that the gas stove 100 is more concise and beautiful when being installed and used.
In this embodiment, the air supply member 50 is a fan and is disposed on the gas delivery assembly 30.
As shown in fig. 9 and 11, specifically, the nozzle holder 32 is formed with a mounting groove 325, the air supply member 50 is clamped in the mounting groove 325, and the air supply member 50 is disposed on a side of the nozzle 34 away from the air mixing pipe 43. Alternatively, the air supply member 50 may be detachably attached to the nozzle holder 32 by a fastener such as a screw.
In this embodiment, as shown in fig. 2, the axial direction of the air mixing pipe 43 is parallel to the bearing surface 21 of the panel 20, the air supply component 50 is located on one side of the gas conveying component 30 away from the air mixing pipe 43, the injection direction of the gas conveying component 30 is consistent with the air outlet direction of the air supply component 50, and the injection direction coincides with the axial direction of the air mixing pipe 43, so as to improve the premixing efficiency and the circulation efficiency of the gas and the air, and the gas and the air can more quickly enter the air mixing chamber 410.
In some embodiments, the air supply 50 may also be disposed on the bearing surface 21 of the panel 20. The air supply member 50 is attached to the bearing surface 21 of the panel 20 by, for example, welding, adhesive, or fasteners such as screws.
In other embodiments, the air supply member 50 may be fixed to an end of the air mixing pipe 43, which is not connected to the combustion portion 41, and disposed on the bearing surface 21 of the panel 20 along with the burner 40. In other words, the gas delivery assembly 30 communicates with the gas mixing pipe 43, the burner 40 is connected to the panel 20 or the gas delivery assembly 30, and the air supply member 50 is fixed to one end of the gas mixing pipe 43 and is not connected to the panel 20 and the gas delivery assembly 30.
Referring to fig. 4, 16 and 17, fig. 16 is a schematic view of the ignition needle assembly shown in fig. 4 in a first position, and fig. 17 is a schematic view of the ignition needle assembly shown in fig. 16 in a second position. The ignition needle assembly 60 is movably arranged on the gas delivery assembly 30, moves to a first position relative to the gas delivery assembly 30 to be positioned above the burner 40 and ignites the burner 40; or from the first position to a second position relative to gas delivery assembly 30, away from burner 40, i.e., away from above burner 40, to facilitate cleaning of burner 40 and the area of panel 20 around burner 40, and further to facilitate removal of burner 40, thereby allowing cleaning of load bearing surface 21 of panel 20.
This application sets up in gas transfer assembly 30 through firing needle subassembly 60 activity to make the independent setting of firing needle subassembly 60 relative combustor 40, there is not the relation of connection promptly between firing needle subassembly 60 and the combustor 40, and then position through adjusting firing needle subassembly 60 to first position, then firing needle subassembly 60 can be to combustor 40 ignition, the position of adjusting firing needle subassembly 60 to second position, in order to avoid the interference of firing needle subassembly 60, and then the region of the panel 20 of the clean combustor 40 of more being convenient for and all sides.
Alternatively, the burner 40 may be fixedly disposed on the bearing surface 21 of the panel 20, and the burner 40 may be detachably disposed on the bearing surface 21 of the panel 20.
In this embodiment, the burner 40 is detachably connected to the panel 20 and/or the gas delivery assembly 30, and will not be described in detail.
As shown in fig. 4, after the ignition needle assembly 60 is adjusted to the second position to be away from the burner 40, the burner 40 can be further detached from the bearing surface 21 to be removed from the bearing surface 21, so that the user can clean the bearing surface 21 of the panel 20 conveniently, the user can clean the burner 40 conveniently, the dead angle of the gas stove 100 can be effectively eliminated, the cleaning difficulty is reduced, and the deep cleaning of the gas stove 100 can be facilitated.
Optionally, the ignition needle assembly 60 is rotatably connected with the fuel gas delivery assembly 30, so that the ignition needle assembly 60 can be rotatably switched between the first position and the second position, and the rotation connection mode is more labor-saving and simple and convenient to use.
Optionally, the ignition needle assembly 60 is snap-fit with the gas delivery assembly 30; wherein, when the ignition needle assembly 60 is clamped on the gas transmission assembly 30, the ignition needle assembly 60 is located at the first position; when the ignition needle assembly 60 is released from the engagement with the gas delivery assembly 30, the ignition needle assembly 60 is withdrawn from above the burner 40 to be away from the burner 40, wherein the positions of the ignition needle assembly 60 away from the burner 40 are the second positions mentioned above.
Specifically, the ignition needle assembly 60 is rotatably connected with the nozzle carrier 32; or the ignition needle assembly 60 may snap fit with the nozzle carrier 32.
Referring to fig. 15, fig. 15 is a schematic view illustrating a connection structure of a firing pin assembly and a gas delivery assembly in the gas range of fig. 1. In some embodiments, the nozzle holder 32 includes a holder body 320 and a connecting arm 326 disposed on the holder body 320, the ignition needle assembly 60 includes a mounting cover 62 and an ignition needle 64, the ignition needle 64 is fixed on the mounting cover 62, the mounting cover 62 is movably connected to the connecting arm 326, and a leg 327 is further disposed on the mounting cover 62 or the holder body 320, and when the mounting cover 62 is located at the first position, the leg 327 is supported between the holder body 320 and the mounting cover 62 to keep the mounting cover 62 located at the first position.
Mounting cap 62 may be rotatably coupled to coupling arm 326 by a shaft or bearing, etc., to rotate between a first position and a second position relative to nozzle carrier 32. Or, the mounting cover 62 is clamped with the connecting arm 326, when the mounting cover 62 is clamped with the connecting arm 326 and the leg 327 is supported between the seat body 320 and the mounting cover 62, the mounting cover 62 is located at the first position; the mounting cap 62 is separated from the connecting arm 326 and is in the second position.
In other embodiments, as shown in fig. 4, the nozzle seat 32 includes a seat body 320 and a support member 328, the seat body 320 is disposed through the mounting opening 22, and the support member 328 is detachably connected to the seat body 320 and covers the mounting opening 22. One end of the mounting cover 62 is movably connected to the support 328, and when the mounting cover 62 is located at the first position, the mounting cover 62 is overlapped on the support 328.
Specifically, the supporting member 328 includes a bottom plate 321 and side plates 323 located at two sides of the bottom plate 321, wherein the bottom plate 321 is connected to the base body 320 and covers the mounting opening 22, one end of the mounting cover 62 is movably connected to one end of each of the two side plates 323, and when the mounting cover 62 is located at the first position, the mounting cover 62 is overlapped on the two side plates 323.
The mounting cover 62 may be rotatably coupled to the two side plates 323 by a rotating shaft, a bearing, or the like. Alternatively, the mounting cover 62 may be clamped to the two side plates 323, and when the mounting cover 62 is clamped to the two side plates 323 and supported by the two side plates 323, the mounting cover 62 is located at the first position; the mounting cover 62 is separated from the two side plates 323 and is in the second position.
Further, as shown in fig. 4, the ignition needle assembly 60 further includes an ion needle 65, the ion needle 65 is fixed to the mounting cover 62, and the ion needle 65 is used to detect whether flames exist in the first air-mixing chamber 411 and the second air-mixing chamber 412. When the ignition needle assembly 60 is located at the first position, the ion needle 65 is located above the combustion portion 41, and it is possible to detect whether flames exist in the first air mixing chamber 411 and the second air mixing chamber 412, and stop the ignition of the ignition needle 64 after the flames are detected, and after the ignition function of the gas stove 100 is started, if the ion needle 65 does not detect the flames, the ignition needle 65 is in a continuous ignition state.
Further, the ignition needle assembly 60 further includes a thermocouple 66, and the thermocouple 66 is fixed to the mounting cap 62 for detecting the flame temperature of the burner 40. When the ignition pin unit 60 is located at the first position, the thermocouple 66 is located above the combustion portion 41, and the flame temperature of the combustion portion 41 can be detected.
Further, as shown in fig. 2, the gas range 100 further includes a controller 83, the controller 83 is electrically connected to the thermocouple 66 and the air supply member 50, the thermocouple 66 is used for detecting the flame temperature when the burner 40 is operated, and the controller 83 is used for adjusting the air output of the air supply member 50 according to the flame temperature detected by the thermocouple 66, so as to adjust the flame temperature by adjusting the air output of the air supply member 50 after the air input of the burner 40 is insufficient and the flame temperature is deviated from the set temperature value due to an excessive increase.
The gas range 100 further comprises a regulating valve 82, the regulating valve 82 is connected to the pipeline 81 leading to the gas delivery assembly 30, and the controller 83 is electrically connected to the regulating valve 82 and is used for regulating the flow rate of the gas provided by the gas delivery assembly 30 through the regulating valve 82 according to the flame temperature detected by the thermocouple 66 so as to regulate the flame temperature.
Specifically, after the gas stove 100 is started, a plurality of flame temperature levels can be set, the controller 83 controls the ignition needle 64 to start ignition, switches of the adjusting valve 82 and the air supply part 50 are opened simultaneously, so that gas and air are mixed in the gas mixing pipe 43, the mixed gas and air enter the gas mixing cavity 410 and are discharged through a fire outlet of the fire cover 413, the mixed gas and air are ignited by an electric arc generated by ignition of the ignition needle 64, the thermocouple 66 detects the flame temperature and feeds the flame temperature back to the controller 83, the controller 83 calculates a real-time flame temperature according to a signal generated by the thermocouple 66, compares the real-time flame temperature with a set flame temperature, and regulates and controls the valve opening of the adjusting valve 82 and the active air intake volume of the air supply part 50 according to temperature deviation, so that the flame temperature is accurately controlled to reach the set flame temperature value.
In this embodiment, referring to fig. 2, 3, 7 and 8, the air mixing chamber 410 includes a first air mixing chamber 411 and a second air mixing chamber 412 that are isolated from each other, the air mixing pipe 43 includes a first air mixing pipe 431 and a second air mixing pipe 432, the first air mixing pipe 431 is communicated with the first air mixing chamber 411, and the second air mixing pipe 432 is communicated with the second air mixing chamber 412; the gas delivery assembly 30 includes a nozzle holder 32 and two nozzles 34, the two nozzles 34 being fixed to the nozzle holder 32 to supply gas to the first gas mixing pipe 431 and the second gas mixing pipe 432, respectively; further, the gas range 100 further includes two regulating valves 82, and the two regulating valves 82 are respectively connected to the two pipelines 81 leading to the corresponding nozzles 34 for independently controlling the flow rate of the corresponding nozzles 34.
By providing a set of the nozzles 34 and the regulating valves 82 corresponding to the first and second gas mixing pipes 431 and 432, respectively, to regulate the gas flow provided from the nozzles 34 to the corresponding first or second gas mixing chamber 411 or 412 by controlling the valve opening of the corresponding regulating valves 82, the flame temperature levels of the first and second gas mixing chambers 411 and 412 can be independently controlled, and interference with each other can be avoided, so that the different flame temperature levels of small, medium, and large fires, etc. can be independently provided regardless of the first or second gas mixing chambers 411 and 412.
Accordingly, as shown in fig. 11, the gas range 100 further includes two air supply members 50, and the two air supply members 50 are disposed on the bearing surface 21 of the panel 20 to independently supply air into the first air mixing pipe 431 and the second air mixing pipe 432, respectively. In other words, the operation states of the two air supply members 50 do not interfere with each other, for example, one of the air supply members 50 is operated, the other air supply member 50 may not be operated, or both air supply members 50 are operated at the same time.
When the nozzle 34 supplies different gas flow rates to the corresponding first gas mixing pipe 431 or second gas mixing pipe 432, the corresponding air supply member 50 supplies an appropriate air flow rate to the corresponding first gas mixing pipe 431 or second gas mixing pipe 432 for premixing, so that the flame temperature level of the corresponding first gas mixing chamber 411 or second gas mixing chamber 412 more efficiently reaches the set flame temperature level.
As shown in fig. 4, 7 and 8, an ignition needle 64 and an ion needle 65 are fixed to the mounting cover 62, the ignition needle 64 is used to ignite the first air-mixing chamber 411 and the second air-mixing chamber 412, and the ion needle 65 is used to detect whether flames exist in the first air-mixing chamber 411 and the second air-mixing chamber 412. When the ignition needle assembly 60 is located at the first position, the ignition portion of the ignition needle 64 is located above the second air mixing chamber 412, and the detection portion of the ion needle 65 extends to the first air mixing chamber 411 across the second air mixing chamber 412, so that whether flames exist in the first air mixing chamber 411 and the second air mixing chamber 412 can be detected simultaneously.
During ignition, the mixture of gas and air in the first gas mixing cavity 411 and the second gas mixing cavity 412 is discharged through the fire outlet of the fire cover 413 and ignited and combusted by the ignition needle 64, after the ion needle 65 detects flame, ignition is finished, and the gas stove 100 further reserves to supply gas and air to the first gas mixing cavity 411 and/or the second gas mixing cavity 412 according to the requirement set by a user; for example, if the user only needs the external fire, the supply of the air to the first air mixing chamber 411 is turned off, and the supply of the air to the second air mixing chamber 412 is kept to supply the flame; or the user only needs the inner ring fire, the air supply to the second air mixing chamber 412 is closed, and the air supply to the first air mixing chamber 411 is reserved to provide the flame; or the user needs to heat and cook globally, the air supply to the first air mixing chamber 411 and the second air mixing chamber 412 is reserved; it is thus achieved that the combustion areas of the first gas-mixture chamber 411 and the second gas-mixture chamber 412 can be independently combusted to provide different combustion areas.
As shown in fig. 7 and 8, when the ignition needle assembly 60 is located at the first position, the detecting portion of the thermocouple 66 crosses over the second air mixing chamber 412 and extends to the first air mixing chamber 411, the thermocouple 66 is used for detecting the flame temperature of the combustion area of the first air mixing chamber 411 and the second air mixing chamber 412, the deviation between the flame temperature and the preset flame temperature can be adjusted in time through the real-time monitoring of the flame temperature by the thermocouple 66, and then the cooking efficiency can be effectively improved.
Referring again to fig. 14, in the present embodiment, the heat-insulating box 70 includes a heat-insulating body 73 and a retaining member 75, the heat-insulating body 73 is connected to the retaining member 75, the retaining member 75 is placed on the bearing surface 21 of the panel 20, that is, the heat-insulating body 73 is disposed on the bearing surface 21 of the panel 20 through the retaining member 75, and the retaining member 75 is detachably connected to the gas delivery assembly 30.
In this embodiment, the retaining member 75 is a box in which the insulator 73 is received, and the box can provide protection for the insulator 73. In other embodiments, the retaining member 75 may be a tray that merely restricts the position of the thermal insulator 73 so that the thermal insulator 73 remains in place relative to the panel 20; the retainer 75 may also be a member connected between the insulator 73 and the gas delivery assembly 30, with one end connected to the insulator 73 and the other end connected to the gas delivery assembly 30. Alternatively, the holder 75 may be detachably attached to the nozzle holder 32, or the holder 75 may be detachably attached to the fixing member 33, or the holder 75 may be detachably attached to the bottom plate 321 of the support member 328.
Wherein, one side of the holding member 75 facing the gas transmission assembly 30 is provided with a first fastening position 840, the nozzle holder 32, the fixing member 33 or the bottom plate 321 is provided with a second fastening position 301, and the first fastening position 840 is fastened with the second fastening position 301. The first fastening position 840 can be a bayonet, and the second fastening position 301 can be a clamping column clamped with the bayonet; or, the first fastening position 840 is a clamping column, and the second fastening position 301 is a bayonet engaged with the clamping column.
In this embodiment, the heat insulating body 73 and the retaining member 75 are provided with openings on the sides thereof facing away from the panel 20, the heat insulating body 73 is accommodated in the retaining member 75 through the openings of the retaining member 75, and the burner 40 is accommodated in the heat insulating body 73 through the openings, so as to recycle the heat overflowing from the burner 40.
Specifically, the heat insulator 73 is provided with a first cavity 71 with an upper opening, the burner 40 is accommodated in the first cavity 71, and the periphery of the burner 40 is wrapped by the heat insulator 73, that is, the heat insulator 73 can gather the heat overflowing from the periphery of the burner 40 at least, so as to reduce the heat overflowing and dissipating loss. The heat insulator 73 is made of heat-collecting material with low thermal conductivity such as mica sheet, glass fiber or firebrick, so that the heat of the whole burner 40 can be completely recycled.
In other embodiments, the retaining member 75 may not be provided, that is, the thermal insulation box 70 only includes the thermal insulation body 73, and the thermal insulation body 73 may also be directly disposed on the bearing surface 21 of the panel 20, for example, the thermal insulation body 73 is magnetically attracted to the bearing surface 21 of the panel 20, or the thermal insulation body 73 is embedded in a limiting groove on the bearing surface 21, or the thermal insulation body 73 is adhered to the bearing surface 21.
Through integrating a whole that generates heat with combustor 40 for combustor 40 becomes the object of generating heat that can be gathered together, and from the bottom surface of combustor 40 and wrap up by the insulator 73 of low coefficient of thermal conductivity all around, only leave the uncovered working space of combustor 40 top and not wrapped up by insulator 73, therefore combustor 40 is from the bottom surface and all around the heat that outwards spills over all can be gathered together by insulator 73, reduce the heat loss that overflows, and can be with the uncovered working space of heat transfer to combustor 40 and combustor 40 top that gathers together, with the heating efficiency of effective promotion combustor 40, and can improve energy utilization.
In this embodiment, the burner 40 includes a combustion portion 41 and a gas mixing pipe 43 connected to the combustion portion 41, wherein the gas mixing pipe 43 is used for mixing gas and guiding gas, the flame on the combustion portion 41 burns to generate heat, and then the heat overflowing from the burner 40 can be recovered by accommodating the combustion portion 41 in the first cavity 71.
The side walls of the heat retaining body 73 and the holding member 75 are each provided with a notch 701, and the gas mixing pipe 43 passes through the notch 701 and extends to the outside of the heat retaining body 73, i.e., to the nozzle 34, so that the nozzle 34 supplies gas to the gas mixing pipe 43, wherein the gas mixing pipe 43 may be connected to the nozzle holder 32 or not connected to the nozzle holder 32.
The notch 701 is used for the air mixing pipe 43 to pass through, the combustion part 41 is accommodated in the first cavity 71, and the heat generated by the combustion part 41 is gathered by the heat insulator 73, so as to improve the heating efficiency and the energy utilization rate.
The heat preservation body 73 is further provided with a second cavity 72, the second cavity 72 is surrounded on the first cavity 71, the pot frame 84 is arranged on the second cavity 72 and framed on the peripheral side of the combustion part 41 to support a pot above the combustion part 41, and the pot frame 84 is further limited by the second cavity 72 and is kept fixed relative to the burner 40.
The pot frame 84 is arranged in the second cavity 72 and is framed on the periphery of the combustion part 41, the heat gathered by the heat retaining body 73 can be partially absorbed by the pot frame 84 and the combustion part 41, the heat loss rate of the combustion part 41 and the pot frame 84 can be reduced, the heat exchange between the combustion part 41 and a pot arranged on the pot frame 84 is more facilitated, the heat gathered by the heat retaining body 73 can also be exchanged with the pot, the heating efficiency and the energy utilization rate are effectively improved, and the heat loss of the burner 40 in the working process is reduced.
Specifically, the pot holder 84 includes a frame body 841 and a plurality of supporting arms 843 spaced apart from the frame body 841, the frame body 841 is located in the second cavity 72 and frames the periphery of the burning portion 41, and the plurality of supporting arms 843 extend out of the heat insulator 73 and support the pot disposed on the burner 40.
In some embodiments, the burner 40 is surrounded by the heat retaining body 73, for example, the heat retaining body 73 is cylindrical, and both ends of the heat retaining body 73 are open, so that the heat retaining body 73 is disposed on the bearing surface 21 and cooperates with the bearing surface 21 to form the first cavity 71 for accommodating the burner 40, or the retaining member 75 covers one end of the heat retaining body 73 to form the first cavity 71, i.e., the heat retaining body 73 only collects heat from the periphery of the burner 40.
In this embodiment, the heat insulator 73 is box-shaped, and the bottom and the periphery of the burner 40 are both wrapped by the heat insulator 73, that is, the heat insulator 73 gathers heat from the bottom and the periphery of the burner 40, so that the heat dissipation loss can be further reduced.
Specifically, the heat insulator 73 includes a bottom wall 731 and a side wall 732 surrounding the bottom wall 731, wherein the bottom wall 731 and the side wall 732 are heat insulating walls, the side wall 732 and the bottom wall 731 form a first cavity 71 and a second cavity 72, the bottom wall 731 supports a bottom surface of the burner 40, the side wall 732 surrounds the burner 40, and a height of the side wall 732 in a direction perpendicular to the bottom wall 731 is greater than or equal to a height of the burner 40.
Specifically, the bottom wall 731 supports the bottom surface of the combustion part 41, the side wall 732 surrounds the combustion part 41, the side wall 732 has a notch 701, and the air-fuel mixture pipe 43 passes through the notch 701 and extends toward the nozzle 34. The bottom wall 731 is used for gathering heat dissipated from the bottom surface of the combustion part 41, and the height of the side wall 732 is greater than or equal to the height of the combustor 40, so that the side wall 732 can gather heat dissipated from the periphery of the combustion part 41, and the heat loss of the combustion part 41 is effectively reduced.
Alternatively, the bottom wall 731 may be a non-insulating wall that serves only as a support structure, such as a grid structure or a ring structure, so that the insulator 73 also draws heat from the periphery of the burner 40.
In other embodiments, the burner 40 and the insulator 73 may not be disposed on the bearing surface 21 of the panel 20, and portions of the burner 40 and the insulator 73 may be disposed in the receiving space 12 formed by the panel 20 and the housing 10. Alternatively, the panel 20 is provided with a cooking opening, the burner 40 and the heat insulator 73 are completely disposed in the accommodating space 12, and a flame is generated at the cooking opening for cooking.
In this embodiment, as shown in fig. 1, the bearing surface 21 of the panel 20 is provided with at least one set of gas delivery assembly 30 and burner 40. When multiple sets of gas delivery assembly 30 and burners 40 are provided on the bearing surface 21 of the panel 20, multiple cooking zones are provided.
Being different from the situation of the prior art, the application discloses a gas stove. Through generating heat wholly with integrated one of combustor for the combustor becomes the object of generating heat that can be gathered together, and will set up the combustor holding on the bearing surface of panel in the first cavity of insulator, and the combustor is wrapped up by the insulator all around, therefore the combustor can be gathered together by the insulator from the heat that outwards spills over all around, reduce the heat and spill over the loss, and can be with the uncovered working space of heat transfer to combustor and combustor top that gathers together, with the heating efficiency of effectively promoting the combustor, and can improve energy utilization.
The above description is only an example of the present application and is not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings, or which are directly or indirectly applied to other related technical fields, are intended to be included within the scope of the present application.
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