CN117387065A - Fire cover, burner and gas stove - Google Patents

Abstract

The application relates to the technical field of gas cookers and discloses a fire cover, a burner and a gas cooker. The fire cover includes: the fire cover body comprises an outer side wall and an inner side wall, wherein the outer side wall is sleeved on the outer side of the inner side wall, the outer side wall and the inner side wall jointly enclose a gas mixing chamber, and the outer side wall is provided with a fire hole communicated with the gas mixing chamber; the top wall is covered and arranged above the gas mixing chamber, the top wall is detachably connected with the fire cover body, and the outer diameter of the top wall is larger than that of the fire cover body. The roof can be dismantled with the fire lid body and be connected, is convenient for with fire lid split like this, and then clean inside or the fire hole of fire lid. The external diameter of roof is greater than the external diameter of fire lid body, like this, after the overflow of pan flows to the roof, can directly flow down along the roof, can not flow to the fire lid body on, can prevent the fire hole jam of fire lid like this, further improved the clean convenience of fire lid.

Description

Fire cover, burner and gas stove

Technical Field

The application relates to the technical field of gas cookers, for example to a fire cover, a burner and a gas cooker.

Background

Most of the existing gas stoves comprise an inner fire cover and an outer fire cover, and double-ring fires are formed through the inner fire cover and the outer fire cover. Alternatively, a multi-ring fire may be formed by increasing the number of fire covers. When the fire cover is used, the fire cover is easily influenced by pot overflow or smoke, and the inside of the fire cover or fire holes are blocked, so that the fire cover needs to be cleaned regularly.

In the process of implementing the embodiments of the present disclosure, it is found that at least the following problems exist in the related art:

the existing fire cover is of an integrated structure, and the fire cover of the integrated structure is inconvenient to clean the interior of the fire cover. Some fire covers can be detached, and the upper cover is provided with a cover plate, and the cover plate is only placed above the fire cover, so that the cover plate is inconvenient to install again after the fire cover is cleaned.

Disclosure of Invention

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview, and is intended to neither identify key/critical elements nor delineate the scope of such embodiments, but is intended as a prelude to the more detailed description that follows.

The embodiment of the disclosure provides a fire cover, a burner and a gas stove, so as to improve the cleaning convenience of the fire cover and facilitate cleaning of the fire cover.

Embodiments of the present disclosure provide a fire cover including: the fire cover body comprises an outer side wall and an inner side wall, wherein the outer side wall is sleeved on the outer side of the inner side wall, the outer side wall and the inner side wall jointly enclose a gas mixing chamber, and the outer side wall is provided with a fire hole communicated with the gas mixing chamber; the top wall is covered and arranged above the gas mixing chamber, the top wall is detachably connected with the fire cover body, and the outer diameter of the top wall is larger than that of the fire cover body.

The embodiment of the disclosure also provides a burner comprising the fire cover.

The embodiment of the disclosure also provides a gas stove, comprising: the burner described above; a housing defining a receiving cavity having an opening, the burner being movably located within the receiving cavity; the lifting assembly is connected with the burner and used for driving the burner to lift between a first position and a second position relative to the accommodating cavity, and when the burner is lifted to the first position, a fire hole of the fire cover is positioned above the opening and used for realizing combustion; when the burner descends to the second position, the fire hole of the fire cover is positioned in the accommodating cavity, and the top wall is abutted with the upper surface of the shell.

The fire cover, the burner and the gas stove provided by the embodiment of the disclosure can realize the following technical effects:

the roof can be dismantled with the fire lid body and be connected, is convenient for with fire lid split like this, and then clean inside or the fire hole of fire lid. The top wall is detachably connected with the fire cover, the fire cover is convenient to detach and mount, and after the top wall and the fire cover body are mounted, the top wall can be guaranteed to be mounted in place, so that the convenience of fire cover mounting is improved. In addition, the external diameter of roof is greater than the external diameter of fire lid body, like this, after the overflow of pan flows to the roof, can directly flow down along the roof, can not flow to the fire lid body on, can prevent like this that the fire hole of fire lid from blockking up, further improved the clean convenience of fire lid.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which like reference numerals refer to similar elements, and in which:

FIG. 1 is a schematic view of a burner raised to a first position according to an embodiment of the present disclosure;

FIG. 2 is a schematic view of a partial structure of a gas range according to an embodiment of the present disclosure;

FIG. 3 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure;

FIG. 4 is a schematic view of a lifting assembly provided in an embodiment of the present disclosure;

FIG. 5 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure;

FIG. 6 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure;

FIG. 7 is a schematic view of a lifter plate according to an embodiment of the present disclosure;

FIG. 8 is a schematic view of a burner according to an embodiment of the present disclosure lowered to a second position;

fig. 9 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure;

FIG. 10 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure;

FIG. 11 is a schematic view of a fire cover provided in an embodiment of the present disclosure;

FIG. 12 is a schematic cross-sectional view of a fire cover provided in accordance with an embodiment of the present disclosure;

FIG. 13 is a schematic view of a partial construction of a fire cover provided in an embodiment of the present disclosure;

FIG. 14 is a partial schematic view of another fire cover provided by an embodiment of the present disclosure;

FIG. 15 is a schematic view of a fire cover from another perspective provided in accordance with an embodiment of the present disclosure;

FIG. 16 is a partial schematic view of another fire cover provided by an embodiment of the present disclosure;

fig. 17 is a schematic structural view of a furnace chamber according to an embodiment of the present disclosure;

FIG. 18 is a schematic view of a burner provided in an embodiment of the present disclosure;

FIG. 19 is a partial schematic view of another combustor provided by an embodiment of the present disclosure;

FIG. 20 is a partial schematic view of another combustor provided by an embodiment of the present disclosure;

FIG. 21 is a schematic view of a damper panel and a damper flap provided by an embodiment of the present disclosure;

FIG. 22 is a schematic view of a structure of a flap provided by an embodiment of the present disclosure;

FIG. 23 is a schematic view showing a partial structure of a gas range according to an embodiment of the present disclosure;

FIG. 24 is a schematic view of a bushing provided by an embodiment of the present disclosure;

FIG. 25 is a schematic view of the top wall of a fire cover provided in accordance with an embodiment of the present disclosure;

fig. 26 is a schematic structural view of another gas range provided in an embodiment of the present disclosure;

FIG. 27 is a schematic view showing a partial structure of another gas range provided in an embodiment of the present disclosure;

fig. 28 is a partial structural schematic view of another gas range provided in an embodiment of the present disclosure;

fig. 29 is a partial structural schematic view of another gas range provided in an embodiment of the present disclosure;

fig. 30 is a schematic view of a partial structure of another gas range provided in an embodiment of the present disclosure.

Reference numerals:

100. a gas range; 1. a housing; 10. a receiving chamber; 101. an opening; 102. a movable opening; 11. a bushing; 111. a clamping groove; 2. a burner; 20. a fire cover; 201. a top wall; 2011. a connecting column; 2012. a third groove; 202. an outer sidewall; 2021. a step-like structure; 203. an inner sidewall; 204. a mixing chamber; 2041. a first cavity; 2042. a second cavity; 2043. a first partition member; 2044. a gap; 2045. a first screw hole; 205. a fire hole; 2051. a first fire hole; 2052. a second fire hole; 206. grooving; 2061. a first slot; 2062. a second slot; 207. a groove; 2071. a first groove; 2072. a second groove; 2073. auxiliary fire holes; 2074. a fire hole; 208. a secondary air passage; 2081. a connection hole; 2082. a connecting rib; 209. a through groove; 2091. an ignition hole; 21. a cavity; 211. a first gas separation channel; 212. a second gas separation channel; 213. a second partition member; 214. a cavity body; 215. connecting edges; 216. a second screw hole; 217. a secondary air flow passage; 22. an ejector assembly; 221. a first ejector; 222. a second ejector; 223. a connecting piece; 224. an ejector; 23. a nozzle; 231. an air door plate; 232. a flap; 233. rotating the column; 234. folding edges; 235. a third through hole; 236. a fourth through hole; 237. a primary air passage; 238. a fourth screw hole; 24. a connecting plate; 241. an elastic member; 242. a second through hole; 3. a lifting assembly; 30. a lifting plate; 301. a guide hole; 302. a first through hole; 31. a hinge rod; 32. a driving mechanism; 321. a slide block; 322. a slide rail; 323. an electric push rod; 4. a lifting rod; 40. a liquid bearing disc; 401. the first avoidance through hole; 402. a second avoidance through hole; 403. a guide rod; 404. a connecting rod; 5. a bracket; 51. a support rod; 6. a thermocouple; 7. an ignition needle; 8. a second lifting assembly; 80. a second lifting plate; 801. a second lifter plate body; 802. a protrusion; 803. the second guide seat; 81. a second driving mechanism; 82. a second slider; 821. an inclined plane; 8211. a first wall surface; 8212. a second wall surface; 8213. a third wall surface; 8214. a pushing part; 8215. a second slide rail; 9. and a second lifting rod.

Detailed Description

So that the manner in which the features and techniques of the disclosed embodiments can be understood in more detail, a more particular description of the embodiments of the disclosure, briefly summarized below, may be had by reference to the appended drawings, which are not intended to be limiting of the embodiments of the disclosure. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may still be practiced without these details. In other instances, well-known structures and devices may be shown simplified in order to simplify the drawing.

The terms first, second and the like in the description and in the claims of the embodiments of the disclosure and in the above-described figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate in order to describe embodiments of the present disclosure. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion.

In the embodiments of the present disclosure, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate an azimuth or a positional relationship based on that shown in the drawings. These terms are used primarily to better describe embodiments of the present disclosure and embodiments thereof and are not intended to limit the indicated device, element, or component to a particular orientation or to be constructed and operated in a particular orientation. Also, some of the terms described above may be used to indicate other meanings in addition to orientation or positional relationships, for example, the term "upper" may also be used to indicate some sort of attachment or connection in some cases. The specific meaning of these terms in the embodiments of the present disclosure will be understood by those of ordinary skill in the art in view of the specific circumstances.

In addition, the terms "disposed," "connected," "secured" and "affixed" are to be construed broadly. For example, "connected" may be in a fixed connection, a removable connection, or a unitary construction; may be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements, or components. The specific meaning of the above terms in the embodiments of the present disclosure may be understood by those of ordinary skill in the art according to specific circumstances.

The term "plurality" means two or more, unless otherwise indicated.

The term "and/or" is an associative relationship that describes an object, meaning that there may be three relationships. For example, a and/or B, represent: a or B, or, A and B.

It should be noted that, without conflict, the embodiments of the present disclosure and features of the embodiments may be combined with each other.

Example 1

As shown in conjunction with fig. 1 to 25, the presently disclosed embodiment provides a gas cooker 100, the gas cooker 100 including a housing 1, a burner 2, and a lifting assembly 3, the housing 1 defining a receiving cavity 10 having an opening 101. The burner 2 comprises a fire cover 20, the burner 2 being movably arranged in the accommodation chamber 10. The lifting assembly 3 is connected with the burner 2 and is used for driving the burner 2 to perform lifting movement between a first position and a second position relative to the accommodating cavity 10, when the burner 2 is lifted to the first position as shown in fig. 1 to 5, the fire hole 205 of the fire cover 20 is positioned above the opening 101 and is used for realizing combustion, and when the burner 2 is lifted to the second position as shown in fig. 8 to 10, the fire hole 205 of the fire cover 20 is positioned in the accommodating cavity 10; the lifting assembly 3 comprises a driving mechanism 32, a lifting plate 30 and a hinge rod 31, wherein the lifting plate 30 can be abutted against or connected with the burner 2, the driving mechanism 32 is positioned below the lifting plate 30, a first end of the hinge rod 31 is rotationally connected with the driving mechanism 32, a second end of the hinge rod 31 is rotationally connected with the lifting plate 30, the driving mechanism 32 can drive the first end of the hinge rod 31 to move towards a first direction or a second direction, and when the driving mechanism 32 drives the first end of the hinge rod 31 to move towards the first direction, the second end of the hinge rod 31 drives the burner 2 to move upwards through the lifting plate 30 so as to enable the burner 2 to move towards the first position from the second position; when the driving mechanism 32 drives the first end of the hinge rod 31 to move towards the second direction, the second end of the hinge rod 31 drives the burner 2 to move downwards through the lifting plate 30, so that the burner 2 moves from the first position towards the second position, wherein the first direction and the second direction are opposite.

In this embodiment, the housing 1 may be understood as a cooking bench, the burner 2 may be movable in the accommodating cavity 10, and when the burner 2 is lifted to the first position, the fire hole 205 of the fire cover 20 of the burner 2 may be lifted above the opening 101, that is, the fire cover 20 may be lifted above the housing 1 for burning, so as to be convenient for heating the cookware and the like above the fire cover 20. When the burner 2 is lowered to the second position, the burner 2 can be wholly or partially accommodated in the accommodating cavity 10, and the fire hole 205 of the fire cover 20 is positioned in the accommodating cavity 10, so that the upper surface of the shell 1 is convenient to clean, and sundries such as soup can not enter the fire hole 205 to block the fire hole 205. And when the user cleans the upper surface of the housing 1, the user can be scalded by the fire cover 20 because all or most of the fire cover 20 is positioned in the accommodating cavity 10.

The actuating mechanism 32 is connected with the first end rotation of articulated rod 31, and when actuating mechanism 32 drive articulated rod 31 moved towards first direction or second direction, the first end of articulated rod 31 rotated with actuating mechanism 32, simultaneously, the second end of articulated rod 31 was moved under the drive of first end, and the second end of articulated rod 31 is connected with lifter plate 30 rotation, and the height of lifter plate 30 can change, and then can realize that lifter plate 30 drives combustor 2 and go up and down. It can be understood that: when the burner 2 is lifted to the first position, the hinge rod 31 extends in the vertical direction, and when the burner 2 is lowered to the second position, the hinge rod 31 extends in the horizontal direction, so that the lifting of the burner 2 can be realized. Moreover, when the hinge rod 31 moves, more height spaces are not required to be reserved in the gas stove 100 to realize movement of the hinge rod 31, the hinge rod 31 can rotate by utilizing the height or the width of the gas stove 100, the lifting plate 30 can be driven to lift in the rotating process, and the movement of the hinge rod 31 is stable and strong, so that the gas stove 100 provided by the embodiment of the disclosure does not need to use more moving rods and can also keep stable lifting, thereby improving the lifting stability of the burner 2. By way of example, the direction indicated by the arrow a in fig. 9 is a first direction, and the direction indicated by the arrow B is a second direction.

Alternatively, the lifter plate 30 can be connected to or abutted against the burner 2, that is, the lifter plate 30 can be directly connected to the burner 2 so that the burner 2 can be lifted up and down with the lifting of the lifter plate 30. Alternatively, the lifter plate 30 is not always in contact with the burner 2, and the lifter plate 30 can be abutted against the burner 2 during movement, thereby driving the burner 2 to lift.

Alternatively, as shown in fig. 2 to 4, the driving mechanism 32 includes a sliding assembly and an electric push rod 323, the sliding assembly includes a sliding block 321 and a sliding rail 322, the sliding block 321 is rotationally connected with the first end of the hinge rod 31, the sliding rail 322 extends along a straight line where the first direction and the second direction are located, and the sliding block 321 is slidably connected with the sliding rail 322. The electric push rod 323 is in driving connection with the slide block 321 and is used for driving the slide block 321 to slide along the slide rail 322.

In this embodiment, the slider 321 is rotatably connected to the first end of the hinge rod 31, the slider 321 can slide along the sliding rail 322, and the electric push rod 323 is used for driving the slider 321 to slide along the sliding rail 322. The electric push rod 323 can drive the sliding block 321 to move along the first direction or the second direction, the sliding block 321 drives the first end of the hinge rod 31 to move along the first direction or the second direction, the hinge rod 31 is rotationally connected with the lifting plate 30, the height of the hinge rod 31 is changed in the moving process of the hinge rod 31, and then the height of the lifting plate 30 is changed, so that the burner 2 can be controlled to perform lifting movement. The sliding mode of the sliding block 321 and the sliding rail 322 is reliable in operation and low in cost.

Alternatively, the first end of the hinge rod 31 is hinged to the slider 321 in such a way as to enable a rotational connection of the hinge rod 31 to the slider 321. Specifically, the first end of the hinge rod 31 is provided with a first rotation hole, the slider 321 is provided with a second rotation hole, and the first rotation shaft penetrates through the first rotation hole and the second rotation hole, so that the first end of the hinge rod 31 can rotate around the slider 321.

Alternatively, the second end of the hinge lever 31 is hinged with the lifter plate 30. Specifically, the second end of the hinge rod 31 is provided with a third rotation hole, the lifting plate 30 is provided with a fourth rotation hole, and the second rotation shaft penetrates through the third rotation hole and the fourth rotation hole, so that the second end of the hinge rod 31 can rotate around the lifting plate 30.

Optionally, the gas stove 100 further includes a spacer, the spacer is disposed between the second end of the hinge rod 31 and the lifting plate 30, specifically, the spacer is disposed between the third rotation hole and the fourth rotation hole, and the spacer is used for preventing friction of the hinge rod 31 during rotation, so as to increase smoothness of rotation of the hinge rod 31.

Optionally, the electric push rod 323 includes a fixed end and a movable end, the fixed end is fixedly disposed on the bottom wall of the accommodating cavity 10, the movable end can move relative to the fixed end, and the movable end is in driving connection with the slide block 321, and the movable end is used for driving the slide block 321 to slide along the slide rail 322.

Optionally, the moving end of the electric push rod 323 moves in the first direction and/or the second direction, so that the slider 321 can move in the first direction and/or the second direction.

Optionally, as shown in fig. 3, the number of sliding components is multiple, at least two sliding components in the multiple sliding components are respectively located at two sides of the combustor 2, the number of the electric push rods 323 is one, and one electric push rod 323 is located between at least two sliding components and connected with the two sliding components.

In this embodiment, the setting of two sliding components can increase the stability that combustor 2 goes up and down, avoids combustor 2 to take place the skew in the lift in-process. One electric putter 323 can drive two sliders 321 motion simultaneously, can reduce cost, and it is limited to hold the space in the chamber 10 moreover, and one electric putter 323 is connected rationally distributed with two slip subassembly, compact structure, can also make two articulated rod 31 motion synchronization that two slip subassemblies correspond to make combustor 2 can stably go up and down, avoid appearing the skew.

In addition, the burner 2 can be driven to lift by one electric push rod 323, so that the problem that the whole burner 2 cannot lift due to the damage of one electric push rod 323 when a plurality of electric push rods 323 are used can be avoided.

Optionally, the gas stove 100 includes a pushing member, where the pushing member is connected to the sliding block 321, and the pushing member is located above the sliding block 321 and is used to abut against the electric push rod 323.

Optionally, a pushing member connects the two sliding blocks 321, as shown in fig. 4, so that one electric push rod 323 can drive the two sliding blocks 321 to move simultaneously, and simultaneously, the movement of the two sliding blocks 321 can be synchronized, so that the lifting of the burner 2 is smoother.

Alternatively, the number of the hinge rods 31 is plural, one slider 321 is correspondingly provided with a plurality of hinge rods 31, and the hinge rods 31 are sequentially arranged on the slider 321 at intervals along the extending direction of the sliding rail 322. As shown in fig. 4, two hinge rods 31 are sequentially provided at intervals on the slider 321. This can increase the lifting stability of the burner 2 in the first direction or the second direction, and prevent the burner 2 from being deviated.

Alternatively, the distance between two adjacent hinge rods 31 of the same slider 321 is greater than or equal to the length of the hinge rod 31, so that enough space can be left on the slider 321 to facilitate the rotation of the hinge rod 31.

Optionally, the setting direction of two slip subassemblies intersects with the straight line that first direction and second direction are located, can guarantee like this that combustor 2 all is equipped with articulated rod 31 along circumference for the lift of combustor 2 is more stable.

As shown in fig. 4, the lifting plate 30 is rectangular, and hinge rods 31 are correspondingly disposed at four corners of the lifting plate 30, so that lifting stability of the lifting plate 30 can be increased.

Alternatively, as shown in fig. 4, the lifter plate 30 is provided with a guide hole 301, and the guide hole 301 penetrates the lifter plate 30 in the thickness direction of the lifter plate 30. The gas stove 100 further comprises a lifting rod 4, wherein the lifting rod 4 is fixedly arranged on the bottom wall of the accommodating cavity 10 and extends upwards, the lifting rod 4 penetrates through the guide hole 301, and the guide hole 301 can move relative to the lifting rod 4; when the first end of the hinge rod 31 moves along the first direction, the second end of the hinge rod 31 rotates relative to the lifting plate 30 and drives the lifting plate 30 to move upwards, and the guide hole 301 of the lifting plate 30 moves upwards along the lifting rod 4 to realize the upwards movement of the burner 2; when the first end of the hinge rod 31 moves in the second direction, the second end of the hinge rod 31 rotates relative to the lifting plate 30 and drives the lifting plate 30 to move downward, and the guide hole 301 of the lifting plate 30 moves downward along the lifting rod 4 to realize the downward movement of the burner 2.

In this embodiment, the guide holes 301 cooperate with the lifting lever 4 to provide a guide for the lifting movement of the lifting plate 30 on the one hand. On the other hand, the guide hole 301 and the lifting lever 4 can restrict the movement of the lifting plate 30 in other directions, so that the lifting plate 30 can only perform lifting movement by the hinge lever 31. This ensures stable lifting and lowering of the burner 2.

Alternatively, the number of the guide holes 301 is plural, and the number of the lifting rods 4 is the same as and corresponds to the number of the guide holes 301 one by one. The plurality of guide holes 301 and the lifting rod 4 can ensure lifting stability of the lifting plate 30.

Alternatively, the plurality of guide holes 301 are provided at intervals in sequence in the circumferential direction of the lifter plate 30, so that the circumferential lifting stability of the lifter plate 30 can be ensured.

For example, as shown in fig. 4, the guide holes 301 are the same as and correspond to the hinge rods 31 one by one. This ensures that the lifting movement of the lifting plate 30 at each hinge lever 31 is stable.

Optionally, the gas stove 100 further includes a guide seat, the guide seat is located in the guide hole 301, and the lifting rod 4 penetrates through the guide seat, and the guide seat is used for reducing friction force of the guide hole 301 moving relative to the lifting rod 4, so that the burner 2 can move more smoothly.

Optionally, the guide holder is provided with a ball, and the ball can reduce the friction between the lifting rod 4 and the guide holder, increase lubrication and improve lifting effect.

Optionally, as shown in fig. 6 to 8, the gas stove 100 further includes a liquid bearing disc 40 and a connecting rod 404, the liquid bearing disc 40 is covered above the opening 101, the liquid bearing disc 40 is provided with a first avoiding through hole 401, and the first avoiding through hole 401 is used for avoiding the burner 2, so as to realize lifting movement of the burner 2. The connecting rod 404 is connected between the underside of the basin 40 and the bottom wall of the receiving chamber 10.

In this embodiment, the liquid-bearing plate 40 is stably connected above the opening 101 through the connecting rod 404, and when the burner 2 is lifted, the fire cover 20 can be lifted above the liquid-bearing plate 40, and the liquid-bearing plate 40 is used for bearing the overflow liquid of the pot, so as to avoid the overflow liquid flowing into the accommodating cavity 10.

Optionally, the tray 40 is attached to the upper surface of the housing 1, that is, there is no gap 2044 between the lower surface of the tray 40 and the upper surface of the housing 1, so that overflow or other impurities can be prevented from entering the accommodating chamber 10.

Optionally, as shown in fig. 1 and 10, the gas stove 100 further includes a support 5, where the support 5 is connected to an upper end of the lifting plate 30 and extends upward, the liquid bearing disc 40 is provided with a second avoidance through hole 402, and the second avoidance through hole 402 is used to avoid the support 5, so as to implement lifting movement of the support 5, and the support 5 is used to support a pot.

In this embodiment, the support 5 is used for supporting the cookware, so that the cookware can be placed. Moreover, a gap 2044 is formed between the bottom of the cooker and the fire cover 20, so that the full combustion of the flame of the fire cover 20 is ensured, and the combustion efficiency is improved. The support 5 is arranged on the lifting plate 30, so that the support 5 can move up and down along with the lifting plate 30, and when the support 5 ascends, the support 5 is used for supporting the cookware. When the support 5 descends, the support can be received in the accommodating cavity 10, so that dead angles of the upper surface of the shell 1 are small, and the upper surface of the shell 1 is convenient to clean.

Alternatively, as shown in fig. 8 and 9, the fire cover 20 includes a top wall 201, the outer diameter of the top wall 201 is larger than the inner diameter of the opening 101 or larger than the inner diameter of the first avoiding through hole 401, and when the burner 2 moves to the second position, the lower surface of the top wall 201 abuts against the upper surface of the housing 1 or the upper surface of the liquid bearing plate 40.

In this embodiment, when the burner 2 descends to the second position, the top wall 201 abuts against the upper surface of the liquid bearing disc 40 or the housing 1, that is, the top wall 201 is covered at the opening 101 or the first avoiding through hole 401, so that the opening 101 or the first avoiding through hole 401 can be plugged, soup and the like are prevented from flowing into the accommodating cavity 10, and the top wall 201 can be used as a part of the housing 1 to form a complete table surface together with the upper surface of the housing 1, so that the burner is convenient to clean and can be used as an extension of a meal preparation area.

In some alternative embodiments, the inner diameter of the first relief through hole 401 of the liquid bearing plate 40 may be larger than the inner diameter of the opening 101, so that the lower surface of the top wall 201 of the fire cover 20 abuts against the upper surface of the housing 1 when the burner 2 is lowered.

In other alternative embodiments, the inner diameter of the first relief through hole 401 of the liquid bearing plate 40 is smaller than or equal to the inner diameter of the opening 101, so that the lower surface of the top wall 201 of the fire cover 20 abuts against the upper surface of the liquid bearing plate 40 when the burner 2 descends.

Alternatively, as shown in fig. 5, 6 and 9, the height of the bracket 5 is greater than the height of the fire cover 20 when the burner 2 is moved to the first position; the burner 2 comprises a fire cover assembly and a connecting plate 24, wherein the fire cover assembly comprises a fire cover 20 and a furnace chamber 21, and the fire cover 20 is arranged above the furnace chamber 21; the connecting plate 24 is positioned above the lifting plate 30 and below the liquid bearing plate 40, the connecting plate 24 is sleeved outside the furnace chamber 21 and connected with the furnace chamber 21, the bracket 5 moves upwards in the process that the first end of the hinge rod 31 moves along the first direction, and the lifting plate 30 can be abutted with the connecting plate 24 so as to drive the connecting plate 24 to move upwards and further drive the fire cover assembly to move upwards; when the first end of the hinge rod 31 moves in the second direction, the lifting plate 30 moves downward, the bracket 5 moves downward, and the lifting plate 30 can be separated from the connecting plate 24, so that the connecting plate 24 drives the fire cover assembly to move downward.

In this embodiment, the height of the bracket 5 is greater than the height of the fire cover 20, so that the cooker can be supported above the fire cover 20, so as to ensure that the flame of the fire cover 20 can be fully combusted. This also results in the burner 2 being lowered, and the support 5 still being partially above the housing 1 when the burner 2 is lowered to the second position. In this embodiment, the connection plate 24 is connected to the burner 2, and the connection plate 24 is located above the lifter plate 30. When the lifting plate 30 moves upwards, the lifting plate 30 drives the bracket 5 to lift, at this time, the burner 2 is located at the second position, the lifting plate 30 is not contacted with the connecting plate 24, after the lifting plate 30 lifts and abuts against the connecting plate 24, the lifting plate 30 can drive the connecting plate 24 to move upwards together, and the connecting plate 24 drives the burner 2 to move upwards together again, and finally the burner moves to the first position. When the lifting plate 30 descends, the lifting plate 30 drives the support 5 to move downwards, the lifting plate 30 moves downwards, the connecting plate 24 drives the burner 2 to move downwards under the action of the gravity of the burner 2 and the connecting plate 24, when the top wall 201 of the fire cover 20 is abutted against the upper surface of the shell 1 or the upper surface of the liquid bearing disc 40, the burner 2 and the connecting plate 24 do not move downwards any more, and the lifting plate 30 drives the support 5 to move downwards until the support 5 is completely contained in the containing cavity 10. Therefore, the bracket 5 and the burner 2 can be both accommodated in the accommodating cavity 10, so that the sanitary dead angle of the upper surface of the shell 1 is reduced, and the cleaning is convenient.

Optionally, the oven cavity 21 includes an oven cavity body 214 and a connecting edge 215, the oven cavity body 214 is located below the fire cover 20, the connecting edge 215 is located at the outer side of the oven cavity body 214 and extends along the circumferential direction of the oven cavity body 214, and the connecting edge 215 is located above the lifter plate 30 and is connected to the connecting plate 24. In this embodiment, the connecting edge 215 is located above the connecting plate 24, and the lifting plate 30 can support the oven cavity 21, so as to further improve the connection stability between the connecting plate 24 and the oven cavity 21.

Optionally, the gas range 100 further includes a connection member 223, and the connection member 223 is connected between the injector 224 and the connection plate 24.

In this embodiment, the connection board 24 is further connected to the ejector 224 of the burner 2 through the connection piece 223, so that the connection stability between the burner 2 and the connection board 24 can be further increased, so as to ensure that the connection board 24 can drive the burner 2 to perform lifting motion.

The connecting piece 223 is L-shaped, the lower end of the connecting piece 223 is connected with the ejector 224, the upper end of the connecting piece 223 is arranged above the connecting plate 24 and is connected with the connecting plate 24 through a screw, so that when the connecting plate 24 is lifted, the ejector 224 can be stably driven to lift, and the lifting of all parts of the combustor 2 is synchronous.

Optionally, as shown in fig. 6, the burner 2 further includes an elastic member 241, where the elastic member 241 is at least partially supported between the connection plate 24 and the liquid bearing plate 40, and when the connection plate 24 moves upward, the elastic member 241 between the connection plate 24 and the liquid bearing plate 40 is elastically deformed.

In this embodiment, when the connecting plate 24 moves upward, the elastic member 241 is elastically deformed. That is, when the connection plate 24 moves downward, the connection plate 24 can not only receive the downward movement of the burner 2 and its own gravity, but also restore the elastic member 241 to exert downward force on the connection plate 24, so that the connection plate 24 can drive the burner 2 to move downward to ensure stable descent of the burner 2.

Alternatively, as shown in fig. 6 and 9, the gas range 100 further includes a guide bar 403, and the guide bar 403 is connected to the lower side of the liquid bearing plate 40. Wherein, the lifting plate 30 is provided with a first through hole 302, the first through hole 302 penetrates through the lifting plate 30 along the thickness direction of the lifting plate 30, the connecting plate 24 is provided with a second through hole 242, and the second through hole 242 penetrates through the connecting plate 24 along the thickness direction of the connecting plate 24; the guide rod 403 sequentially penetrates the second through hole 242 and the first through hole 302 and then extends below the lifting plate 30, and when the lifting plate 30 moves, the first through hole 302 and the second through hole 242 can both move relative to the guide rod 403.

In this embodiment, the guide bar 403 enables the lifting plate 30 and the connecting plate 24 to maintain stability in the lifting direction during lifting, and prevents the burner 2 from being deviated in other directions.

Optionally, the elastic member 241 is at least partially located in the second through hole 242 and sleeved outside the guide rod 403.

In this embodiment, the elastic member 241 is sleeved on the outer side of the guide rod 403 and is disposed in the second through hole 242, so that there is no need to install the elastic member 241 at another position, and the stress positions of the elastic member 241 and the guide rod 403 are consistent, so that the combustor 2 can be prevented from being deflected due to different forces received by the connecting plate 24 and the lifting plate 30 during lifting.

Optionally, the number of the burners 2 is plural, and each burner 2 is provided with a driving mechanism 32 and a lifting plate 30, so that the lifting of different burners 2 of the gas stove 100 do not affect each other, and the convenience of using the gas stove 100 is improved.

Alternatively, when the number of the burners 2 is plural, the arrangement direction of the plural burners 2 intersects with a straight line in which the first direction and the second direction are located. This can avoid interference between the electric pushers 323 of the plurality of burners 2. By way of example, as shown in fig. 9, the two burners 2 are disposed along the length direction of the accommodating cavity 10, and the straight lines where the first direction and the second direction are located are disposed along the width direction of the accommodating cavity 10, so that the electric push rod 323 is convenient to be disposed, the electric push rod 323 is not required to be disposed in a space, the size of the gas stove 100 is not increased, and the use flexibility of the gas stove 100 is ensured.

Optionally, the burner 2 includes a fire cover 20, a furnace chamber 21, and an injector 224, the fire cover 20 being disposed above the furnace chamber 21, the injector 224 being in communication with the furnace chamber 21 for providing gas or a mixture of gas and primary air (hereinafter collectively referred to as gas) to the furnace chamber 21 and the fire cover 20.

The fire cover 20 defines a gas mixing chamber, and a fire hole 205 communicated with the gas mixing chamber is formed in a side wall of the fire cover 20, wherein the fire hole 205 is used for combustion so as to realize combustion of the fire cover 20.

Optionally, the number of the burners 2 is plural, the ejectors 224 extend along the setting direction of the plural burners 2, as shown in fig. 9, the two burners 2 are set along the length direction of the accommodating chamber 10, the straight line where the first direction and the second direction are located is set along the width direction of the accommodating chamber 10, and the ejectors 224 of each burner 2 face the adjacent burners 2, so that the installation positions of the ejectors 224 and the electric push rod 323 can be prevented from conflicting. It should be noted that: the ejector 224 in this embodiment extends along the setting direction of a plurality of combustors 2, and is not strictly required to be in the same straight line, and the extending direction of the ejector 224 slightly deviates also, so that the form of avoiding the interference of the ejector 224 and the electric push rod 323 can be realized, which belongs to the optional embodiment of the present application.

As shown in fig. 11-16, the disclosed embodiment also provides a fire cover 20, the fire cover 20 defining a first cavity 2041 and a second cavity 2042, the first cavity 2041 being located above the second cavity 2042, the first cavity 2041 being adapted to communicate with the first injector 221, the second cavity 2042 being adapted to communicate with the second injector 222. Wherein, the side wall of the fire cover 20 is provided with a first fire hole 2051 and a second fire hole 2052, the first fire hole 2051 is communicated with the first cavity 2041, and the second fire hole 2052 is communicated with the second cavity 2042. The flame holes 205 include a first flame hole 2051 and a second flame hole 2052, and the mixing chamber 204 includes a first chamber 2041 and a second chamber 2042.

In this embodiment, the fire cover 20 integrates the first cavity 2041 and the second cavity 2042 on one fire cover 20, and then the two rings of fire can be formed by matching the first fire hole 2051 and the second fire hole 2052, so that a plurality of fire covers 20 are not required to be arranged, the sanitary dead angle of the gas stove 100 can be reduced, and the cleaning convenience is improved. In addition, the first cavity 2041 is located above the second cavity 2042, that is, the first cavity 2041 and the second cavity 2042 are provided with two cavities by using the height direction of the fire cover 20, so that the diameter of the fire cover 20 can be reduced, the space occupied by the fire cover 20 can be further reduced, the sanitary dead angle can be reduced, and the cleaning convenience of the gas stove 100 can be improved.

In this embodiment, the burner 2 can be lifted, and two rings of fires can be realized only by arranging one fire cover 20, and the complexity of lifting the burner 2 can be reduced by one fire cover 20, so that the burner is more convenient to clean.

Alternatively, the first ejector 221 may be one of the inner ejector 224 and the outer ejector 224, and the second ejector 222 may be the other of the inner ejector 224 and the outer ejector 224. That is, the ejectors 224 corresponding to the first cavity 2041 and the second cavity 2042 may be adjusted according to actual conditions.

Alternatively, as shown in fig. 11, both the first and second flame holes 2051 and 2052 are provided to the outer side wall 202 of the flame cover 20, and the first flame hole 2051 is located above the second flame hole 2052.

In this embodiment, the first flame holes 2051 and the second flame holes 2052 are formed in the same side wall of the flame cover 20, so that the intensity of flame can be increased, and the first flame holes 2051 are located below the second flame holes 2052, so that the flame at the first flame holes 2051 can stabilize the flame at the second flame holes 2052.

It should be noted that: the first fire holes 2051 and the second fire holes 2052 may not be located on the same side wall, for example, the first fire holes 2051 are located on the top wall 201 of the fire cover 20, and the second fire holes 2052 are located on the side wall of the fire cover 20, so that the area of the flame can be increased. Therefore, the user can set the positions of the first and second flame holes 2051 and 2052 according to actual needs.

Optionally, the number of the first fire holes 2051 is plural, the plurality of first fire holes 2051 are sequentially arranged at intervals along the circumferential direction of the fire cover 20, the number of the second fire holes 2052 is plural, and the plurality of second fire holes 2052 are sequentially arranged at intervals along the circumferential direction of the fire cover 20. Wherein, the first fire holes 2051 and the second fire holes 2052 are staggered.

In this embodiment, the first fire holes 2051 and the second fire holes 2052 are all disposed along the circumference of the fire cover 20, so that the fire cover 20 can be ignited along the circumference, and thus the pot can be heated uniformly. The first and second flame holes 2051 and 2052 are alternately arranged, so that the first and second flame holes 2051 and 2052 can be prevented from competing for air, and smoke is reduced.

Optionally, the fire cover 20 is further configured with a slit (hereinafter, collectively referred to as a second slit 2062 for convenience of distinction), and the second slit 2062 extends in the circumferential direction of the fire cover 20 and penetrates the plurality of second fire holes 2052.

In this embodiment, the second notch 2062 can prevent the second flame holes 2052 from being detached from flame, and can increase the flame transmission speed of the second flame holes 2052 in the circumferential direction of the flame cover 20, thereby further improving the flame stabilizing effect on the first flame holes 2051.

Alternatively, the second flame holes 2052 have a smaller aperture than the first flame holes 2051.

In this embodiment, the first fire hole 2051 is above, and the aperture of the first fire hole 2051 is larger, so that the flame combustion intensity of the fire cover 20 can be ensured, the second fire hole 2052 is located below the first fire hole 2051, and can play a role in stabilizing flame, and the aperture of the second fire hole 2052 is smaller than that of the first fire hole 2051, so that the flame at the second fire hole 2052 and the flame at the first fire hole 2051 can be prevented from competing for air, or the flame at two fire holes 205 is prevented from crossing, and the generation of smoke can be reduced.

Alternatively, as shown in fig. 12 and 13, the fire cover 20 includes a top wall 201, an outer side wall 202, and an inner side wall 203, the top wall 201 being circular-like. The outer side wall 202 is annular and the outer side wall 202 is located below the top wall 201. The inner side wall 203 is annular, the inner side wall 203 is located below the top wall 201 and inside the outer side wall 202, and the top wall 201, the outer side wall 202 and the inner side wall 203 jointly enclose to form a mixing cavity 204. The fire cover 20 further includes a first partition member 2043, where the first partition member 2043 is located in the air mixing chamber 204, is connected to the inner wall surface of the outer side wall 202, and has a gap 2044 between the outer wall surface of the inner side wall 203, the first partition member 2043 partitions the air mixing chamber 204 into a first cavity 2041 and a second cavity 2042, and the first cavity 2041 is adapted to communicate with the first injector 221 through the gap 2044.

In this embodiment, the first partition member 2043, the inner side wall 203 and the outer side wall 202 together partition the air mixing cavity 204 into a first cavity 2041 and a second cavity 2042, the first cavity 2041 is located above the second cavity 2042, and the first cavity 2041 is communicated with the first injector 221 through a gap 2044, so that the first cavity 2041 and the second cavity 2042 can be communicated with the corresponding injector 224, and normal combustion of the fire cover 20 can be ensured.

Alternatively, the first flame holes 2051 are inclined upward in the inside-out direction. By this arrangement, the flow rate of the fuel gas at the first flame holes 2051 can be increased, and the flame intensity at the first flame holes 2051 can be further increased.

Optionally, the second flame holes 2052 are inclined upward in the inside-out direction. By this arrangement, the flow rate of the fuel gas at the second flame holes 2052 can be increased, and the flame intensity at the second flame holes 2052 can be further increased.

Optionally, the fire cover 20 comprises connecting spokes connected between the first partition 2043 and the inner side wall 203, which can increase the strength of the first partition 2043. Optionally, a plurality of connection spokes are provided at intervals once in the circumferential direction of the fire cover 20, so that the strength of the first partition 2043 can be ensured, and the flow of the fuel gas in the gap 2044 can be prevented.

Alternatively, as shown in fig. 12 and 19, the inlet end of the second flame holes 2052 is provided at the junction of the first partition 2043 and the outer side wall 202 of the flame cover 20, and the second flame holes 2052 are inclined upward in the inside-to-outside direction.

In this embodiment, since the first fire hole 2051 is inclined upward in the direction from inside to outside, in order to ensure that the second fire hole 2052 is not too far from the first fire hole 2051, the second fire hole 2052 is disposed as far as possible, and therefore, the inlet end of the second fire hole 2052 is disposed at the junction between the first partition member 2043 and the outer sidewall 202 of the fire cover 20, and the second fire hole 2052 is inclined upward in the direction from inside to outside, so that the height of the second fire hole 2052 can be increased as much as possible. Moreover, the outlet ends of the first fire hole 2051 and the second fire hole 2052 are close to the upper part of the fire cover 20, so that the distance between the flame and the cooker can be reduced, the flame of the fire cover 20 can be ensured to burn the cooker, and the burning effect is improved.

Optionally, the first partition 2043 includes a first wall section and a second wall section, a gap 2044 exists between one end of the first wall section and an outer wall surface of the inner side wall 203, one end of the second wall section is connected to the other end of the first wall section, the other end of the second wall section is connected to an inner wall surface of the outer side wall 202, and the second wall section is inclined upward in the direction from inside to outside.

In this embodiment, the second wall section is inclined upwardly, that is, the wall section of the first partition 2043 adjacent to the outer side wall 202 is inclined upwardly, so that the second flame holes 2052 can be further disposed upwardly.

In some alternative embodiments, the fire cover 20 may be divided into two parts, where the fire cover 20 is divided into a top wall 201 and a fire cover body, the fire cover body includes an outer sidewall 202 and an inner sidewall 203, the outer sidewall 202 is sleeved on the outer side of the inner sidewall 203, the inner sidewall 203 and the outer sidewall 202 jointly enclose to form a gas mixing chamber, and the outer sidewall 202 is provided with a fire hole 205 communicated with the gas mixing chamber. The roof 201 covers the top of locating the gas mixing chamber, and roof 201 and fire lid body detachable connection, and the external diameter of roof 201 is greater than the external diameter of fire lid body.

The top wall 201 is detachably connected with the fire cover body, so that the fire cover 20 is convenient to be detached, and the inside of the fire cover 20 or the fire hole 205 of the fire cover 20 is cleaned. The top wall 201 is detachably connected with the fire cover 20, so that the fire cover 20 is convenient to detach and mount, and after the top wall 201 and the fire cover body are mounted, the top wall 201 can be ensured to be mounted in place, so that the convenience of mounting the fire cover 20 is improved. In addition, the external diameter of roof 201 is greater than the external diameter of fire lid body, like this, after the overflow of pan flows to roof 201, can directly flow down along roof 201, can not flow to the fire lid body on, can prevent like this that fire hole 205 of fire lid 20 from blockking up, further improved the clean convenience of fire lid 20. In addition, the outer diameter of the top wall 201 is larger than the outer diameter of the fire cover body, so that the top wall 201 can be abutted against the upper surface of the liquid bearing plate 40 or the upper surface of the casing 1 after the fire cover 20 descends.

Alternatively, as shown in fig. 12, 13 and 25, the cross section of the top wall 201 is circular, the lower surface portion of the top wall 201 extends downward to form a connecting post 2011, the fire cover body is provided with a connecting hole 2081, and the connecting hole 2081 extends in the thickness direction of the fire cover body. Wherein, the connecting post 2011 is configured with a connecting portion, the connecting hole 2081 is configured with a connecting matching portion adapted to the connecting portion, and when the connecting post 2011 is inserted into the connecting hole 2081, the connecting portion can be matched with the connecting matching portion to connect the fire cover body and the top wall 201.

In this embodiment, the connection post 2011 and the connection hole 2081 are connected through a connection portion and a connection mating portion, so that the connection between the top wall 201 and the fire cover body can be achieved. Through spliced pole 2011 and connecting hole 2081 realization connection, need not to establish a plurality of screw holes in addition at roof 201 and fire lid body, reduce the use of screw, can reduce the installation complexity to realize the roof 201 and fire lid body's connection.

Optionally, the connecting post 2011 is located at the center of the top wall 201, so that the top wall 201 is connected with the fire cover body more stably, and the top wall 201 can be prevented from being deflected when the top wall 201 is subjected to external force.

Optionally, the connecting portion includes external threads, and the connecting mating portion includes internal threads, the external threads being adapted to the internal threads.

In this embodiment, the external thread and the internal thread cooperate, and the installation and the disassembly of the top wall 201 and the fire cover body can be realized by rotating the top wall 201, so that tools are not needed, screws are not needed to be additionally arranged, and the users do not need to worry about the screw loss during the installation and the disassembly. Moreover, by means of the connection between the internal thread and the external thread, the top wall 201 is more tightly connected with the fire cover body, so that the air leakage of the air mixing cavity 204 can be prevented.

Alternatively, as shown in fig. 13, 14 and 16, the fire cover 20 further defines a secondary air passage 208, and the secondary air passage 208 penetrates the bottom wall of the fire cover 20 in the thickness direction of the fire cover 20 and communicates with the outside. The outlet end of the secondary air passage 208 communicates with the fire hole 205. The fire cover 20 also defines a through slot 209, the through slot 209 extending radially through the fire cover 20 and communicating with the secondary air passage 208 after passing through the fire cover 20. The inlet end of the through groove 209 is communicated with the outlet end of the secondary air channel 208, the outlet end of the through groove 209 is communicated with the outside, and secondary air flowing out of the secondary air channel 208 can flow to the fire hole 205 along the through groove 209. Specifically, the inner sidewall 203 of the fire cover 20 encloses the secondary air passage 208, that is, the secondary air passage 208 is located inside the inner sidewall 203, and the through slot 209 penetrates the inner sidewall 203 and the outer sidewall 202 of the fire cover 20. Arrows in fig. 16 indicate the flow direction of the secondary air in the through-slots 209.

In the present embodiment, the secondary air passage 208 is provided inside the inner side wall 203, so that the arrangement of the fire hole 205 and the air mixing chamber 204 can be ensured, and the supply of secondary air can be ensured. The arrangement is reasonable in layout of the fire cover 20, the effect is remarkable, and the secondary air channel 208 and the through groove 209 can provide secondary air for the fire hole 205 of the fire cover 20 so as to ensure that flames at the fire hole 205 can be fully combusted and reduce smoke.

Optionally, the fire cover body further includes a connecting rib 2082, the connecting rib 2082 is located in the secondary air channel 208 and connected to an inner wall surface of the inner sidewall 203, where the connecting hole 2081 is located on the connecting rib 2082.

In this embodiment, the connection ribs 2082 facilitate the arrangement of the connection holes 2081, so as to connect the fire cover body with the top wall 201. For example, as shown in fig. 13, the number of the connecting ribs 2082 is plural, and the plurality of connecting ribs 2082 are arranged in a crossing manner, so that the strength of the connecting ribs 2082 can be increased, the strength of the connecting holes 2081 can be further ensured, and finally, the stable connection between the top wall 201 and the fire cover body can be realized.

Alternatively, the projections of the fire holes 205 are located in the top wall 201 in a downward-to-upward direction.

In this embodiment, the projections of the fire holes 205 are all located in the top wall 201, so that the top wall 201 can block the soup from flowing into the fire holes 205, thereby avoiding the fire holes 205 from being blocked.

The presently disclosed embodiments also provide a burner 2 including a fire cover 20 of any of the embodiments described above.

The burner 2 provided in the embodiments of the present disclosure, because of including the fire cover 20 in any of the embodiments described above, has the beneficial effects of the fire cover 20 in any of the embodiments described above, and will not be described in detail herein.

Optionally, as shown in fig. 17 to 22, the burner 2 further includes a furnace chamber 21 and an injector assembly 22, the furnace chamber 21 is located below the fire cover 20, the furnace chamber 21 defines a first gas separation channel 211 and a second gas separation channel 212, the second gas separation channel 212 is sleeved outside the first gas separation channel 211, the first gas separation channel 211 is communicated with the first cavity 2041, and the second gas separation channel 212 is communicated with the second cavity 2042. The injector assembly 22 includes a first injector 221 and a second injector 222, the first gas separation channel 211 is communicated between the first injector 221 and the first cavity 2041, and the second gas separation channel 212 is communicated between the second injector 222 and the second cavity 2042.

In this embodiment, the furnace chamber 21 is configured to communicate the ejector 224 with the fire cover 20, and can split the fuel gas flowing into the ejector 224 to guide the fuel gas flowing out of different ejectors 224 to the corresponding fire cover 20. Because the gap 2044 exists between the first partition member 2043 and the inner side wall 203, the second cavity 2042 is located outside the gap 2044, the second cavity 2042 is communicated with the second air distribution channel 212 located outside, and the first cavity 2041 is communicated with the first air distribution channel 211 located inside through the gap 2044, so that the two cavities of the fire cover 20 can be ensured to have fuel gas inflow, and normal combustion of the fire cover 20 can be ensured.

Optionally, as shown in fig. 19, arrows indicate the flowing direction of the fuel gas, a step structure 2021 is configured below the outer side wall 202 of the fire cover 20, and when the fire cover 20 is covered over the oven cavity 21, the outer side wall 202 of the oven cavity 21 is matched with the step structure 2021.

In this embodiment, the outer side wall 202 of the fire cover 20 is connected with the outer side wall 202 of the oven cavity 21 through the step structure 2021, so that the end face seal and the radial seal are realized between the outer side wall 202 of the fire cover 20 and the outer side wall 202 of the oven cavity 21, the sealing degree of the fire cover 20 is increased, and air leakage is avoided.

Alternatively, the cavity 21 includes a second partition member 213, the second partition member 213 being located within the cavity 21, the second partition member 213 partitioning the cavity 21 into a first gas separation channel 211 and a second gas separation channel 212; when the fire cover 20 is disposed over the cavity 21, the upper surface of the second partition 213 abuts against the lower surface of the first partition 2043.

In the present embodiment, the first partition 2043 abuts against the second partition 213, that is, the first partition 2043 and the second partition 213 are end-face-sealed, so that the convenience of mounting the flame cover 20 and the cavity 21 can be improved.

Alternatively, the lower surface of the inner sidewall 203 of the flame cover 20 abuts against the upper surface of the inner sidewall 203 of the cavity 21, that is, the lower surface of the inner sidewall 203 of the flame cover 20 is sealed with the inner sidewall 203 of the cavity 21, which can further improve the convenience of installation of the flame cover 20 and the cavity 21.

It should be noted that: the inner side wall 203 of the fire cover 20 and the inner side wall 203 of the oven cavity 21 may be in a form of combining end face seal and radial seal, and the first partition member 2043 and the second partition member 213 may also be in a form of combining end face seal and radial seal, so that in practical application, a user may set a connection mode of the two parts according to needs, and the connection mode of the fire cover 20 and the oven cavity 21 may be realized, which all belong to an alternative embodiment of the present application.

Optionally, the fire cover 20 is detachably connected to the cavity 21.

In this embodiment, the fire cover 20 is detachably connected with the oven cavity 21, so that the fire cover 20 and the oven cavity 21 can be conveniently taken out, the fire cover 20 and the oven cavity 21 can be conveniently detached and installed, and meanwhile, the fire cover 20 and the oven cavity 21 can be conveniently cleaned.

Optionally, the fire cover 20 is connected to the cavity 21 by screws. Specifically, the first blocking member 2043 is provided with a first screw hole 2045, the second blocking member 213 is provided with a second screw hole 216, the first screw hole 2045 and the second screw hole 216 are correspondingly provided, and a screw penetrates the first screw hole 2045 and the second screw hole 216 to be connected.

Alternatively, as shown in fig. 14, the number of the first screw holes 2045 is plural, the first screw holes 2045 are sequentially arranged at intervals in the circumferential direction of the fire cover 20, and the number of the second screw holes 216 is the same as and corresponds to the first screw holes 2045 one by one, so that the connection stability of the fire cover 20 and the cavity 21 can be increased.

Alternatively, as shown in fig. 17, the cavity 21 further defines a secondary air flow passage 217, the secondary air flow passage 217 penetrates the cavity 21 in the thickness direction of the cavity 21, the secondary air flow passage 217 is located inside the first air separation passage 211, the secondary air flow passage 217 is located below the secondary air passage 208, and the secondary air flow passage 217 communicates between the outside and the secondary air passage 208 such that outside air flows into the secondary air passage 208 through the secondary air flow passage 217.

In this embodiment, since the oven cavity 21 is located below the fire cover 20, in order to ensure that the secondary air passage 208 can communicate with the outside, the oven cavity 21 also defines a secondary air flow passage 217 that communicates with the outside, so that the secondary air passage 208 can communicate with the outside. That is, the secondary air enters the secondary air flow channel 217 from the bottom of the cavity 21, then flows into the secondary air channel 208 through the secondary air flow channel 217, flows from the secondary air channel 208 to the through slot 209, and finally flows to the fire hole 205, so as to ensure that the flame at the fire hole 205 can be fully combusted.

Optionally, as shown in fig. 13, the burner 2 further includes a thermocouple 6 and an ignition needle 7, the outer side wall 202 of the fire cover 20 is partially recessed inward to form a groove 207, and the thermocouple 6 or the ignition needle 7 is disposed in the groove 207, or the thermocouple 6 and the ignition needle 7 are respectively disposed in the two grooves 207.

In this embodiment, the outer side wall 202 of the fire cover 20 is concaved inward to form a groove 207, and the groove 207 may be used for placing the thermocouple 6 or the ignition needle 7, or the fire cover 20 may be provided with two grooves 207 for placing the thermocouple 6 and the ignition needle 7, respectively. The thermocouple 6 and the ignition needle 7 can be hidden in the fire cover 20, and the fire cover 20 can protect the thermocouple 6 and/or the ignition needle 7 from external wind power and liquid overflow, so that the thermocouple 6 and/or the ignition needle 7 can work normally.

In the related art, the thermocouple 6 and the ignition needle 7 are generally disposed outside the inner fire cover 20, and the fire cover 20 of the present application is an integral fire cover 20, and the fire cover 20 itself can form a two-ring fire. The thermocouple 6 and the ignition needle 7 are arranged at the groove 207, so that the integrated fire cover 20 also has the functions of flameout protection and ignition, and the normal use of the burner 2 can be ensured.

It should be noted that: the arrangement of the thermocouple 6, the ignition needle 7 and the groove 207 provided in the embodiments of the present disclosure is not limited to the form of the fire cover 20 of the present application, and other forms of the fire cover 20 may also be configured with the groove 207 of the present application, and the fire cover 20 in the manner of arranging the thermocouple 6 and/or the ignition needle 7 by arranging the groove 207 belongs to the alternative embodiments of the present application.

Alternatively, as shown in fig. 13 and 15, when the thermocouple 6 is positioned in the groove 207, (for convenience of distinction, the groove 207 corresponding to the thermocouple 6 is collectively referred to as a second groove 2072), the side wall of the second groove 2072 is provided with an auxiliary fire hole 2073, the auxiliary fire hole 2073 is in communication with the air mixing chamber 204, the auxiliary fire hole 2073 corresponds to the thermocouple 6, and the auxiliary fire hole 2073 is used for burning the thermocouple 6.

In this embodiment, the second groove 2072 is correspondingly provided with an auxiliary fire hole 2073, and the auxiliary fire hole 2073 can burn the thermocouple 6 all the time, so that the thermocouple 6 cannot flameout and power off, and thus the normal operation of the thermocouple 6 can be ensured.

Alternatively, as shown in fig. 15, the number of auxiliary fire holes 2073 is plural, and at least two of the plurality of auxiliary fire holes 2073 are respectively located at opposite side walls of the second recess 2072.

In this embodiment, the thermocouple 6 is located in the second recess 2072, and at least two auxiliary fire holes 2073 are located on the side wall of the second recess 2072, so that it can be further ensured that the flame of the auxiliary fire holes 2073 can burn the thermocouple 6, so as to improve the fire protection performance of the thermocouple 6.

Optionally, the fire hole 205 is located outside the second recess 2072, and the side wall of the second recess 2072 is further provided with a fire transfer hole 2074, the fire transfer hole 2074 is located between the fire hole 205 and the auxiliary fire hole 2073, and the fire transfer hole 2074 is used for transferring the flame of the fire hole 205 to the auxiliary fire hole 2073.

Optionally, since the thermocouple 6 is disposed in the second groove 2072, the second groove 2072 may not have a fire hole 205 for burning, and in order to ensure that the auxiliary fire hole 2073 is provided with fire, the side wall of the second groove 2072 is further provided with a fire transfer hole 2074, and the fire transfer hole 2074 can transfer the flame at the fire hole 205 to the auxiliary fire hole 2073, so as to ensure that the auxiliary fire hole 2073 can burn, and further ensure that the auxiliary fire hole 2073 can continuously burn the thermocouple 6.

Optionally, a flame transfer hole 2074 is located between the first flame hole 2051 and the auxiliary flame hole 2073.

In this embodiment, since the thermocouple 6 has a certain height, the auxiliary fire hole 2073 needs to be disposed at a higher position so as to burn the thermocouple 6, in order to ensure smooth fire transfer, the fire transfer hole 2074 is located between the first fire hole 2051 and the auxiliary fire hole 2073, so that the distance of fire transfer can be reduced, and the flame at the first fire hole 2051 can be smoothly transferred to the auxiliary fire hole 2073.

Optionally, both the fire transfer holes 2074 and the auxiliary fire holes 2073 are in communication with the second cavity 2042.

In this embodiment, the fire transfer holes 2074 and the auxiliary fire holes 2073 are both communicated with the second cavity 2042, and the first fire holes 2051 can be understood as the main fire holes 205 because the apertures of the first fire holes 2051 are larger, when the flame of the fire cover 20 needs to be reduced, the first injector 221 can be controlled not to intake air, so that the first cavity 2041 has no fuel gas, and the first fire holes 2051 have no flame. At this time, the second injector 222 is kept supplying gas, and the second cavity 2042 contains gas, so that the second flame holes 2052 can burn, and thus a small flame mode of the flame cover 20 can be realized. In order to ensure that the thermocouple 6 still can work normally when the fire cover 20 is in the small fire mode, the fire transfer holes 2074 and the auxiliary fire holes 2073 are communicated with the second cavity 2042, so that the thermocouple 6 can be ensured to have flame all the time.

Optionally, the fire transfer holes 2074 have a larger aperture than the first fire holes 2051. This can increase the flame intensity at the fire transfer holes 2074 to ensure the success rate of the transfer of fire. And when the first fire hole 2051 does not catch fire, the fire transfer hole 2074 may transfer fire with the second fire hole 2052.

Optionally, the aperture of the auxiliary fire hole 2073 is smaller than the aperture of the fire transmission hole 2074, and the flame at the auxiliary fire hole 2073 only needs to burn the thermocouple 6, so that a larger aperture is not required, and the auxiliary fire hole 2073 and the fire hole 205 are prevented from competing for fuel gas.

Alternatively, as shown in fig. 16, the projection of the thermocouple 6 and/or the ignition needle 7 is located entirely within the fire cover 20 in a top-to-bottom direction.

In this embodiment, the projections of the thermocouple 6 and the ignition needle 7 are located entirely within the fire cover 20 in the top-to-bottom direction, which can be understood as: the thermocouple 6 and/or the ignition needle 7 are all positioned in the groove 207 so that the thermocouple 6 and/or the ignition needle 7 do not obstruct the elevating movement of the burner 2 when the burner 2 is elevating and lowering, and combustion of the fire cover 20 can be achieved.

It should be noted that: for the lifting gas stove 100, the thermocouple 6 and/or the ignition needle 7 are arranged on the outer side of the fire cover 20, so that the lifting of the fire cover 20 is easy to influence, the thermocouple 6 and/or the ignition needle 7 are completely arranged in the groove 207, and the thermocouple 6 can be always burnt through the auxiliary fire hole 2073, so that the combustor 2 can be kept lifted, and the thermocouple 6 and the ignition needle 7 can be still arranged to ensure the normal operation of the combustor 2.

Optionally, the thermocouple 6 is detachably connected or fixedly connected with the fire cover 20; and/or the ignition needle 7 is detachably connected or fixedly connected with the fire cover 20.

In this embodiment, the ignition needle 7 and/or the thermocouple 6 are connected to the fire cover 20, so that the ignition needle 7 and/or the thermocouple 6 can move along with the fire cover 20, and when the fire cover 20 is lifted, the ignition needle 7 and/or the thermocouple can also lift, so as to avoid interference of the ignition needle 7 and/or the thermocouple 6 on the lifting of the burner 2.

For convenience of distinction, as shown in fig. 13, the corresponding groove 207 of the ignition needle 7 is referred to as a first groove 2071, and in some alternative embodiments, the first groove 2071 extends in the radial direction of the fire cover 20 and communicates with the secondary air passage 208 through the fire cover 20, that is, the first groove 2071 extending through the fire cover 20 in the radial direction of the fire cover 20 and communicating with the secondary air passage 208 may serve as the through groove 209. The ignition needle 7 is positioned in the through groove 209, and after the ignition needle 7 ignites, the flame can be transferred to the fire hole 205 of the fire cover 20.

In this embodiment, the secondary air flowing out from the secondary air channel 208 to the through groove 209 flows to the outer fire hole 205 of the fire cover 20 along the direction from inside to outside through the through groove 209, so that sufficient secondary air can be provided for the ignition needle 7 to ensure that the ignition needle 7 can successfully ignite, and the ignition success rate of the ignition needle 7 can be improved. In addition, secondary air is supplied to the fire holes 205 of the outer side wall 202 of the fire cover 20, so that the combustion of the fire holes 205 is more sufficient, and the generation of smoke can be reduced.

Optionally, at least one side wall of the through groove 209 is provided with an ignition hole 2091, the ignition hole 2091 is communicated with the air mixing cavity 204, and the ignition hole 2091 is used for matching with the ignition needle 7 to ignite, and can transfer flame to the fire hole 205.

In this embodiment, the side wall of the through groove 209 is provided with an ignition hole 2091, the ignition hole 2091 is communicated with the air mixing cavity 204, and the ignition needle 7 is matched with the ignition needle 7 for ignition, so that normal ignition of the burner 2 can be ensured.

Optionally, the fire cover 20 is further provided with a slot 206, one end of the slot 206 is located below the ignition hole 2091, and the other end of the slot 206 is located at the fire hole 205, wherein the slot 206 extends partially along the circumference of the fire cover 20 and penetrates at least one fire hole 205, and the flame at the ignition hole 2091 can be transferred to the fire hole 205 through the slot 206.

In this embodiment, the slot 206 can transfer the flame at the ignition hole 2091 to the flame hole 205, so as to increase the speed of flame transfer and ensure the success rate of flame transfer.

Optionally, one side wall of the through groove 209 is provided with a plurality of ignition holes 2091, and the plurality of ignition holes 2091 are sequentially spaced apart in a radial direction of the fire cover 20.

In this embodiment, the plurality of ignition holes 2091 are sequentially spaced along the radial direction of the fire cover 20, so that after the ignition needle 7 ignites, the flame can be transferred along the radial direction of the fire cover 20 along the plurality of ignition holes 2091 to be transferred to the fire hole 205 outside the through groove 209.

Optionally, one side wall of the through groove 209 is provided with a plurality of ignition holes 2091, and the other side wall is provided with only one ignition hole 2091, so that ignition of the ignition needle 7 can be ensured, and after the ignition needle 7 ignites, flame can be transferred to the fire hole 205 from only one side wall of the through groove 209 and then transferred to the whole fire cover 20 along the circumferential direction of the fire cover 20, so that the transfer of flame in two directions can be avoided, and collision is caused. As an example, as shown in fig. 13, one side wall of the through groove 209 is provided with 4 ignition holes 2091, and the other side wall is provided with one ignition hole 2091.

Alternatively, the ignition hole 2091 communicates with the first cavity 2041, and the ignition needle 7 operates only when the burner 2 is ignited, and thus, the ignition needle 7 communicates with the first cavity 2041, so that the ignition of the ignition needle 7 can be achieved. And the top of firing pin 7 is the firing end, and the position of ignition hole 2091 needs the higher that sets up, and ignition hole 2091 is like the intercommunication with first cavity 2041, can reduce the preparation degree of difficulty of ignition hole 2091, reduce cost.

Alternatively, the slots 206 include a first slot 2061 extending through a portion of the first flame holes 2051 and a second slot 2062 extending through all of the second flame holes 2052, the first slot 2061 extending through all of the second flame holes 2052.

In the present embodiment, the first slit 2061 is only used to transfer the flame at the ignition hole 2091 to the first flame hole 2051, and therefore, the first slit 2061 penetrates part of the first flame hole 2051 to realize flame transfer. The second cut-out 2062 not only can transfer fire, but also can increase the fire transfer speed between the plurality of second fire holes 2052 and increase the flame stabilizing capability of the second fire holes 2052 to the first fire holes 2051.

Optionally, as shown in fig. 20, the burner 2 further comprises a nozzle 23, a damper plate 231 and a damper plate 232. The nozzle 23 is in communication with the inlet of the eductor 224 and the nozzle 23 is not in contact with the eductor 224. The air door panel 231 is provided at the inlet of the ejector 224 and is located between the nozzle 23 and the ejector 224. The air flap 232 is arranged on one side of the air door plate 231 facing the nozzle 23, the air flap 232 is rotationally connected with the air door plate 231, and the ejector 224 comprises a first ejector 221 and a second ejector 222.

In this embodiment, the air door plate 231 is disposed at the inlet of the ejector 224, that is, the air door plate 231 is mounted on the ejector 224, so that the position of the air door plate 231 can be relatively fixed. The air flap 232 is rotatably connected to the air flap 231, and the air flap 232 is mounted on the air flap 231, so that the air flap 232 can be mounted on the one hand. On the other hand, the air flap 232 can rotate relative to the air door plate 231, and the air flap 232 does not move back and forth, so that the air flap 232 can adjust the primary air quantity flowing through the air door plate 231, and finally can adjust the primary air quantity flowing into the ejector 224, and the flexibility of flame adjustment of the gas stove 100 is improved. The ejector 224 does not contact with the nozzle 23, can improve the injection volume of primary air, and the air door sheet 231 and the air door sheet 232 of the embodiment of the disclosure are matched again for the combustion efficiency of the gas stove 100 is higher, and the combustion is more abundant.

In addition, when the burner 2 is a liftable burner, the nozzle 23 does not contact the ejector 224, and the entire burner 2 can be lifted. In addition, the air door plate 231 and the air flap 232 can be arranged in the application, so that the lifting combustor 2 can also adjust the inlet amount of primary air, and the combustion efficiency of the combustor 2 is improved

It should be noted that: the air flap 232 and the air flap 231 of the present application may be applied to other types of burners 2, and are not limited to the burner 2 with the lifting rod 4, and the air flap 231 and the air flap 232 of the present application may be applied to the burner 2 with the nozzle 23 and the ejector 224 non-contact ejection. Even the in-line gas range 100 in which the nozzle 23 contacts the injector 224 may employ the damper plate 231 and the damper plate 232 of the present application.

Alternatively, as shown in fig. 21 and 22, the damper plate 231 defines a third through hole 235 and a primary air passage 237, and the damper sheet 232 can block a portion of the primary air passage 237. The wall portion of the air flap 232 facing the air flap 232 protrudes toward the air flap 232 to form a rotating column 233, the rotating column 233 is provided with a fourth through hole 236, the fourth through hole 236 penetrates the rotating column 233 along the thickness direction of the air flap 232, the fourth through hole 236 is communicated with the inlet of the ejector 224, the fourth through hole 236 is correspondingly communicated with the nozzle 23 and is not contacted with the nozzle 23, the rotating column 233 can be inserted into the third through hole 235, and the rotating column 233 can rotate relative to the third through hole 235, so that the air flap 232 is rotationally connected with the air flap 231, and the air flap 232 can adjust the area of the opening 101 of the primary air channel 237 to adjust the flow rate of primary air.

In this embodiment, the rotation post 233 and the third through hole 235 are rotatably connected, so that the rotational connection between the damper plate 231 and the damper plate 232 can be realized. At the same time, the rotary column 233 is provided with a fourth through hole 236, and the fourth through hole 236 is correspondingly communicated with the nozzle 23 and is not in contact with the nozzle 23, that is, the fourth through hole 236 can ensure that the fuel gas flowing out of the nozzle 23 can flow into the ejector 224. In this way, the damper plate 231 and the damper plate 232 can be rotated and inflow of fuel gas can be ensured.

Optionally, the rotating post 233 further includes a rotating post 233 body and a flange 234, the rotating post 233 body is provided with a fourth through hole 236, and the rotating post 233 body can penetrate through the third through hole 235. The folded edge 234 is located at one end of the rotating post 233, which faces the air door plate 231, the folded edge 234 protrudes from the connecting post 2011, and along the thickness direction of the air door plate 231, the projection of the folded edge 234 is located on the air door plate 231, so that the folded edge 234 limits the rotating post 233 to separate from the third through hole 235.

In this embodiment, the folded edge 234 plays a role of limiting, and can limit the rotation column 233 from separating from the third through hole 235, that is, the folded edge 234 can limit the movement of the air flap 232 relative to the air door panel 231 in the front-back direction, so that the air flap 232 can only rotate relative to the air door panel 231.

Alternatively, the flange 234 has a ring shape, and the flange 234 extends in the circumferential direction of the rotation post 233, and the outer diameter of the flange 234 is larger than the outer diameter of the third through hole 235.

In this embodiment, the folded edge 234 is annular, so that the folded edge 234 can play a limiting role along the circumferential direction of the rotating post 233, and thus the limiting role of the folded edge 234 can be increased. The outer diameter of the folded edge 234 is larger than that of the third through hole 235, so that the folded edge 234 cannot fall off from the third through hole 235 in the circumferential direction, and the limit effect of the folded edge 234 is improved

Optionally, the damper plate 231 is detachably or fixedly connected to the ejector 224.

In this embodiment, the air door plate 231 is connected with the ejector 224, so that the connection stability of the air door plate 231 can be increased, and further, the connection stability and the rotation stability of the air door plate 232 can be ensured.

As illustrated in fig. 20 and 21, the damper 231 is connected to the ejector 224 by a screw, the ejector 224 is provided with a third screw hole, the damper plate 231 is provided with a fourth screw hole 238, and the screw passes through the third screw hole and the fourth screw hole 238 to connect the ejector 224 to the damper plate 231.

Optionally, the first ejector 221 and the second ejector 222 are arranged side by side, an air door plate 231 is arranged at the inlet of the first ejector 221 and the inlet of the second ejector 222, two air door plates 232 are correspondingly arranged at the air door plate 231, and the air door plates 232 and the ejectors 224 are in one-to-one correspondence. Two fourth screw holes 238 are respectively provided at both ends of an air door plate 231 to ensure connection stability of the air door plate 231.

The disclosed embodiments also provide a gas stove 100 comprising the burner 2 of any of the embodiments described above.

The gas stove 100 provided in the embodiments of the present disclosure, because of including the burner 2 in any of the embodiments described above, has the beneficial effects of the burner 2 in any of the embodiments described above, and will not be described in detail herein.

Alternatively, as shown in fig. 23, the accommodating chamber 10 of the gas cooker 100 has a movable port 102, the movable port 102 is communicated with the accommodating chamber 10, and when the burner 2 moves to the first position, the fire hole 205 is located above the movable port 102, so as to realize the combustion of the fire cover 20. The gas range 100 further includes a bushing 11, and the bushing 11 is disposed at an edge of the movable port 102 and protrudes from an upper surface of the housing 1. When the burner 2 is lowered to the second position, the lower surface of the top wall 201 of the fire cover 20 abuts against the liner 11.

In this embodiment, when the burner 2 is lowered to the second position, the lower surface of the top wall 201 of the fire cover 20 abuts against the liner 11, so that the liner 11 can reduce the adsorption force between the lower surface of the top wall 201 of the fire cover 20 and the upper surface of the housing 1, thereby reducing the jamming in the lifting process of the burner 2, and reducing the heat transfer of the fire cover 20 to the housing 1. In addition, the lining 11 protrudes from the upper surface of the casing 1, so that water on the upper surface of the fire cover 20 or water on the upper surface of the casing 1 can be prevented from flowing into the accommodating cavity 10, and the lining 11 plays a certain role in blocking.

It should be noted that: the movable opening 102 in the embodiment of the present disclosure is the opening 101 or the first avoiding through hole 401, so that the bushing 11 may be disposed on the housing 1 or the liquid bearing disc 40. Specifically, when the inner diameter of the first avoidance through hole 401 is larger than the inner diameter of the opening 101, the bushing 11 is disposed at the opening 101, and when the inner diameter of the first avoidance through hole 401 is smaller than or equal to the inner diameter of the opening 101, the bushing 11 is disposed at the first avoidance through hole 401.

Alternatively, as shown in fig. 24, the bush 11 is configured with a catching groove 111, the notch of the catching groove 111 faces the edge of the movable port 102, and the catching groove 111 is fitted with the edge of the movable port 102 so that the bush 11 is mounted at the edge of the movable port 102.

In this embodiment, the clamping groove 111 is convenient for the bushing 11 to be stably installed at the edge of the movable opening 102, so that the bushing 11 is convenient to install and detach, and further the gas stove 100 is convenient to clean.

Alternatively, the bush 11 is annular, and the bush 11 is matched with the top wall 201 so that the top wall 201 can abut against the bush 11 in the circumferential direction thereof.

In this embodiment, the annular bush 11 enables the bush 11 to abut against the top wall 201 in the circumferential direction, and also prevents the flow of soup or water into the accommodating chamber 10 in the circumferential direction of the movable port 102.

Optionally, the lower wall of the top wall 201 is recessed upwardly to form a recess (hereinafter referred to as a third recess 2012 for ease of distinction), and the upper end of the liner 11 is located within the third recess 2012 when the burner 2 is moved to the second position.

In this embodiment, the third groove 2012 is configured to avoid the liner 11, so that when the combustor 2 moves to the second position, the liner 11 can abut against the top wall 201 of the third groove 2012, so as to avoid jamming caused by lifting of the combustor 2.

Alternatively, when the burner 2 moves to the second position, the lower wall surface of the outer side wall 202 of the third recess 2012 abuts against the upper wall surface of the housing 1.

In this embodiment, when the burner 2 moves to the second position, the outer side wall 202 of the third recess 2012 abuts against the housing 1, so that the soup or water can be further prevented from flowing into the third recess 2012, and further the soup or water is prevented from flowing into the accommodating cavity 10.

The second embodiment is different from the first embodiment in that:

the embodiment of the present disclosure also provides another way of lifting and lowering the gas cooker 100, and as shown in fig. 26 to 30, the gas cooker 100 includes a housing 1, a burner 2, and a second lifting assembly 8. The housing 1 defines a containing cavity 10 having an opening 101; the burner 2 comprises a fire cover 20, the burner 2 being movably arranged in the accommodation chamber 10. The second lifting assembly 8 is connected with the burner 2 and is used for driving the burner 2 to perform lifting movement between a first position and a second position relative to the accommodating cavity 10, when the burner 2 is lifted to the first position, the fire hole 205 of the fire cover 20 is located above the opening 101 and is used for realizing combustion, and when the burner 2 is lifted to the second position, the fire hole 205 of the fire cover 20 is located in the accommodating cavity 10. The lifting assembly 3 comprises a second driving mechanism 81, a second sliding block 82 and a second lifting plate 80, the second lifting plate 80 is connected with the burner 2, the second driving mechanism 81 is in driving connection with the second sliding block 82, an inclined plane 821 is formed on the upper wall surface of the second sliding block 82, the second lifting plate 80 is positioned above the second sliding block 82 and is abutted against the inclined plane 821, and when the second driving mechanism 81 drives the second sliding block 82 to move along the third direction or the fourth direction, the second lifting plate 80 can move along the inclined plane 821 so as to adjust the height of the second lifting plate 80, and further the burner 2 can move between the first position and the second position; wherein the third direction is opposite to the fourth direction, and a straight line where the third direction and the fourth direction are located intersects the vertical direction.

In this embodiment, the housing 1 may be understood as a cooking bench, the burner 2 may be movable in the accommodating cavity 10, and when the burner 2 is lifted to the first position, the fire hole 205 of the fire cover 20 of the burner 2 may be lifted above the opening 101, that is, the fire cover 20 may be lifted above the housing 1, and the fire cover 20 may be burned, so as to be convenient for heating a pot or the like above the fire cover 20. When the burner 2 is lowered to the second position, the burner 2 can be wholly or partially accommodated in the accommodating cavity 10, and the fire hole 205 of the fire cover 20 is positioned in the accommodating cavity 10, so that the upper surface of the housing 1 can be cleaned conveniently, and a user can be scalded by the fire cover 20 when cleaning the upper surface of the housing 1.

The second lifting plate 80 is located above the second slider 82 and abuts against the second slider 82, that is, the second lifting plate 80 and the second slider 82 are disposed along a vertical direction. And the straight line where the third direction and the fourth direction are located intersects with the vertical direction, so that the second slider 82 can move toward the third direction or the fourth direction with respect to the second lifter plate 80 during sliding, and since the height of the inclined surface 821 is changed, the height of the second lifter plate 80 is also changed during movement of the second slider 82 since the second lifter plate 80 abuts against the inclined surface 821, the height of the second lifter plate 80 can be adjusted, and thus the lifting of the burner 2 can be achieved. The second slider 82 is located and holds the intracavity 10, and the space of the direction of height that occupies is less, utilizes the width and/or the length direction of gas-cooker 100 self just can set up second slider 82, can not occupy the space outside gas-cooker 100 casing 1, reduces the existence at the outside dead angle of gas-cooker 100, and then is convenient for clear up gas-cooker 100's casing 1 upper surface etc. has improved gas-cooker 100's cleaning performance. And the lifting is realized by adopting the mode of matching the second lifting plate 80 with the inclined plane 821, the structure is simple, the realization is easy, the stability is strong, and the lifting stability of the burner 2 can be improved.

Optionally, the straight lines in which the third direction and the fourth direction are located are perpendicular to the vertical direction, that is, the straight lines in which the third direction and the fourth direction are located may be horizontal directions, the straight lines in which the third direction and the fourth direction are located may be the length or the width direction of the accommodating cavity 10, and of course, the straight lines in which the third direction and the fourth direction are located may be slightly offset from the horizontal directions. As an example, as shown in fig. 30, the direction indicated by the arrow of C is the fourth direction, and the direction indicated by the arrow of D is the third direction.

Alternatively, as shown in fig. 28, the inclined surface 821 includes a first wall 8211, a second wall 8212, and a third wall 8213, and the first wall 8211 is in a horizontal plane. The second wall 8212 is a horizontal plane and is located at one end of the first wall 8211, and the height of the second wall 8212 is smaller than the height of the first wall 8211. The third wall 8213 is connected between the first wall 8211 and the second wall 8212.

In this embodiment, the height of the second wall 8212 is smaller than the height of the first wall 8211, and the third wall 8213 is connected between the first wall 8211 and the second wall 8212, so that the third wall 8213 is inclined, and when the second lifter plate 80 moves to the third wall 8213, the height of the second lifter plate 80 starts to change, and the height of the second lifter plate 80 can be adjusted. The first wall 8211 and the second wall 8212 play a role of buffering, so that the lifting process of the second lifting plate 80 is smoother, and no sudden drop or sudden rise occurs.

Optionally, the gas stove 100 further includes a second sliding rail 8215, where the second sliding rail 8215 is disposed along a straight line where the third direction and the fourth direction are located, the second sliding rail 8215 is slidably connected to the second sliding block 82, and the second driving mechanism 81 can drive the second sliding block 82 to slide along the second sliding rail 8215.

In this embodiment, the second sliding rail 8215 is used for sliding the second sliding block 82, so that the second sliding block 82 can slide in the third direction or the fourth direction, and the second sliding block 82 is prevented from sliding in other directions.

Optionally, the second driving mechanism 81 includes a second electric push rod, where the second electric push rod is connected with the second slider 82 in a driving manner, and the second electric push rod can drive the second slider 82 to move toward the third direction or the fourth direction. The second electric push rod is reliable in movement and good in continuity, so that the combustor 2 can be lifted and lowered more smoothly.

Alternatively, as shown in fig. 27 and 28, the second lifter plate 80 includes a second lifter plate body 801 and a protrusion 802, and the second lifter plate body 801 is connected to the burner 2. The protrusion 802 is located below the second lifter plate body 801 and abuts against the inclined surface 821.

In this embodiment, the second lifter plate body 801 is configured to drive the burner 2 to perform a lifting motion, and the protrusion 802 is configured to abut against the inclined surface 821, that is, the protrusion 802 is a stress point of the second lifter plate 80. The protrusion 802 facilitates the abutment of the second lifting plate 80 with the inclined surface 821, thereby lifting the burner 2.

Alternatively, as shown in fig. 29, the number of the burners 2 is plural, and the number of the second sliders 82 is the same as the number of the burners 2 and corresponds one to one, wherein one second driving mechanism 81 is connected to at least two second sliders 82.

In this embodiment, one second driving mechanism 81 is connected to at least two second sliders 82, and the number of the second sliders 82 is the same as that of the burners 2 and corresponds to one. It can be understood that: one second driving mechanism 81 drives at least two burners 2 to be lifted, so that the number of the second driving mechanisms 81 can be reduced, thereby reducing the cost of the gas cooker 100.

As shown in fig. 29, for example, two burners 2 are sequentially spaced along the length direction of the accommodating chamber 10, and correspondingly, two second sliders 82 corresponding to the two burners 2 are also sequentially spaced along the length direction of the accommodating chamber 10, and the second driving mechanism 81 is located between the two second sliders 82 and also located between the two burners 2. In this way, the second driving mechanism 81 makes full use of the space between the two burners 2 in the gas stove 100, and the second driving mechanism 81 is not required to be additionally arranged, so that the size of the gas stove 100 is not increased, and the gas stove 100 can be more flexibly applied.

It should be noted that: the number of the second driving mechanisms 81 may be plural, and each second slider 82 is in driving connection with one second driving mechanism 81, so that the elevation of each burner 2 is independent, and the burners 2 do not interfere with each other, thereby increasing the flexibility of using the gas stove 100.

Optionally, a second lifting plate 80 includes at least two protrusions 802, and the number of the at least two protrusions 802 is the same as and corresponds to the number of the at least two second sliders 82.

In this embodiment, one second lifter plate 80 includes at least two protrusions 802, that is, one second lifter plate 80 is connected to at least two burners 2 at the same time, and one second lifter plate 80 cooperates with one second driving mechanism 81 to enable at least two burners 2 to be lifted synchronously, so that the second lifter plate 80 is prevented from moving out of synchronization due to cooperation of different second lifter plates 80 with one second driving mechanism 81.

Optionally, the second lifting plate 80 is provided with a second guiding hole, and the second guiding hole penetrates through the second lifting plate 80 along the thickness direction of the second lifting plate 80; the gas range 100 further includes a second elevating rod 9, the second elevating rod 9 is provided at the bottom wall of the accommodating chamber 10 and extends upward, and the second guide hole can slide along the second elevating rod 9 when the second elevating plate 80 moves.

In this embodiment, the second guide hole cooperates with the second lifting lever 9 to provide a guide for the lifting movement of the second lifting plate 80 on the one hand. On the other hand, the second guide hole and the second elevating bar 9 can restrict the movement of the second elevating plate 80 in other directions, so that the second elevating plate 80 can only perform elevating movement by the inclined surface 821. This ensures stable lifting and lowering of the burner 2.

Alternatively, the number of the second guide holes is plural, and the plural second guide holes are provided at intervals along the circumferential direction of the burner 2, so that the stability of the elevation of the burner 2 can be increased.

Optionally, the gas stove 100 further includes a second guiding seat 803, the second guiding seat 803 is located in the second guiding hole, the second lifting rod 9 penetrates through the second guiding seat 803, and the second guiding seat 803 is used for reducing friction force of the second guiding hole moving relative to the second lifting rod 9, so that the movement of the burner 2 is smoother.

Optionally, the second guide 803 is provided with balls, which can reduce the friction between the second lifting rod 9 and the second guide 803, increase lubrication, and improve lifting effect.

Optionally, the bottom of the protrusion 802 is conical, so that the contact area between the protrusion 802 and the inclined surface 821 can be reduced appropriately, so that the protrusion 802 and the inclined surface 821 can be abutted conveniently, and the size of the inclined surface 821 does not need to be too large, so that space can be further saved.

Alternatively, the second lifter plate 80 is sleeved outside the cavity 21, and the second lifter plate 80 is connected with the cavity 21.

In this embodiment, the second lifting plate 80 is sleeved on the outer side of the furnace chamber 21, so that on one hand, the lifting movement of the burner 2 is not disturbed, and on the other hand, because the furnace chamber 21 is larger, the position of the furnace chamber 21 is moderate, and the second lifting plate 80 is connected with the furnace chamber 21, so that the connection stability with the burner 2 can be increased, and the second lifting plate 80 can stably drive the burner 2 to perform the lifting movement.

Optionally, the connecting edge 215 is disposed above the second lifter plate 80 and is connected to the second lifter plate 80. In this embodiment, the connecting edge 215 is located above the second lifter plate 80, and the second lifter plate 80 can support the oven cavity 21, so as to further improve the connection stability between the second lifter plate 80 and the oven cavity 21.

Alternatively, the cavity 21 is detachably or fixedly connected to the second lifter plate 80. Wherein the detachable connection facilitates the assembly and disassembly of the cavity 21 and the second lifter plate 80 and cleaning. The fixed connection increases the connection strength of the cavity 21 and the second lifter plate 80. Specifically, the connecting edge 215 is detachably connected to the second lifter plate 80 by a screw.

Optionally, an ejector 224 is located below the second lifter plate 80 and communicates with the oven cavity 21. The connection member 223 is connected between the ejector 224 and the second lifter plate 80.

In this embodiment, the second lifting plate 80 is further connected to the ejector 224 of the burner 2 through the connecting piece 223, so that the connection stability between the burner 2 and the second lifting plate 80 can be further increased, so as to ensure that the second lifting plate 80 can drive the burner 2 to perform lifting motion.

As shown in fig. 29, the connecting piece 223 is L-shaped, the lower end of the connecting piece 223 is connected with the ejector 224, and the upper end of the connecting piece 223 is set up above the second lifting plate 80 and is connected with the second lifting plate 80 through a screw, so that when the second lifting plate 80 lifts, the ejector 224 can be stably driven to lift, and the lifting of each part of the burner 2 is synchronized.

Optionally, the gas range 100 further includes a support 5 and a support rod 51, and the support 5 is used for supporting the cookware. The support rod 51 is connected between the bracket 5 and the bottom wall of the accommodating chamber 10; the second lifter plate 80 has seted up first hole of dodging, and first hole of dodging runs through second lifter plate 80 along the thickness direction of second lifter plate 80, and the second hole of dodging has been seted up to the roof 201 of casing 1, and the second hole of dodging runs through the roof 201 of casing 1 along the thickness direction of roof 201 of casing 1, and first hole of dodging is corresponding with the second hole of dodging, and bracing piece 51 is connected with support 5 after penetrating through first hole and the second hole of dodging in proper order.

In this embodiment, the support 5 is fixedly connected to the gas stove 100 through the support rod 51, that is, the support 5 cannot be lifted along with the burner 2, so that the support 5 can be provided with a larger size, so as to ensure that cookers with various sizes and weights can be supported, and ensure the normal use of the gas stove 100.

Alternatively, the number of the holders 5 is plural, and the number of the support rods 51 is the same as and corresponds to the number of the holders 5 one by one, so that each holder 5 can be stably supported on the gas cooker 100.

The above description and the drawings illustrate embodiments of the disclosure sufficiently to enable those skilled in the art to practice them. Other embodiments may include structural and other modifications. The embodiments represent only possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in, or substituted for, those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A fire cover, comprising:

the fire cover body comprises an outer side wall and an inner side wall, wherein the outer side wall is sleeved on the outer side of the inner side wall, the outer side wall and the inner side wall jointly enclose a gas mixing chamber, and the outer side wall is provided with a fire hole communicated with the gas mixing chamber;

the top wall is covered and arranged above the gas mixing chamber, the top wall is detachably connected with the fire cover body, and the outer diameter of the top wall is larger than that of the fire cover body.

2. A fire cover as claimed in claim 1, wherein,

the cross section of the top wall is similar to a circle, the lower surface part of the top wall extends downwards to form a connecting column, the fire cover body is provided with a connecting hole, and the connecting hole extends along the thickness direction of the fire cover body;

the connecting column is provided with a connecting portion, the connecting hole is provided with a connecting matching portion matched with the connecting portion, and when the connecting column is inserted into the connecting hole, the connecting portion can be matched with the connecting matching portion so as to connect the fire cover body with the top wall.

3. A fire cover as claimed in claim 2, wherein,

the connecting portion comprises external threads, the connecting matching portion comprises internal threads, and the external threads are matched with the internal threads.

4. A fire cover as claimed in claim 2, wherein,

the fire cover defines a secondary air passage which penetrates through the bottom wall of the fire cover along the thickness direction of the fire cover and is positioned on the inner side of the inner side wall;

the fire cover body further includes:

and the connecting ribs are positioned in the secondary air channel and connected with the inner wall surface of the inner side wall, and the connecting holes are formed in the connecting ribs.

5. A fire cover as claimed in any one of claims 1 to 4 wherein,

the roof with the chamber jointly forms the chamber that mixes, the fire lid body still includes:

the first partition piece is positioned in the air mixing cavity and divides the air mixing cavity into a first cavity and a second cavity, the first cavity is positioned above the second cavity, the first cavity is suitable for being communicated with the first ejector, and the second cavity is suitable for being communicated with the second ejector;

the fire holes comprise a first fire hole and a second fire hole, the first fire hole is communicated with the first cavity, and the second fire hole is communicated with the second cavity.

6. The fire cover of claim 5 wherein the fire cover is a fire cover,

one end of the first partition member is connected with the inner wall surface of the outer side wall, and a gap exists between the other end of the first partition member and the outer wall surface of the inner side wall;

The first cavity is located above the first partition member and is suitable for being communicated with the first ejector through the gap, and the second cavity is located below the first partition member.

7. A burner comprising a fire cover as claimed in any one of claims 1 to 6.

8. The burner of claim 7, further comprising:

the furnace chamber is positioned below the fire cover, the furnace chamber is defined with a first gas distribution channel and a second gas distribution channel, and the second gas distribution channel is sleeved on the outer side of the first gas distribution channel;

the ejector assembly comprises a first ejector and a second ejector, wherein the first air separation channel is communicated between the first ejector and the first cavity, and the second air separation channel is communicated between the second ejector and the second cavity.

9. A burner as claimed in claim 8, wherein,

the furnace chamber is further defined with a secondary air flow passage, the secondary air flow passage penetrates through the furnace chamber along the thickness direction of the furnace chamber, the secondary air flow passage is positioned on the inner side of the first air dividing passage, the secondary air flow passage is positioned below the secondary air passage, and the secondary air flow passage is communicated between the outside and the secondary air passage, so that outside air flows into the secondary air passage through the secondary air flow passage.

10. A gas cooker, characterized by comprising:

a burner as claimed in any one of claims 7 to 9

A housing defining a receiving chamber having an opening, the burner being movably disposed within the receiving chamber;

the lifting assembly is connected with the burner and used for driving the burner to lift between a first position and a second position relative to the accommodating cavity, and when the burner is lifted to the first position, a fire hole of the fire cover is positioned above the opening and used for realizing combustion; when the burner descends to the second position, the fire hole of the fire cover is positioned in the accommodating cavity, and the top wall is abutted with the upper surface of the shell.