Gas hob
By equipping each burner of the gas stove with an independent base and an upper and lower sliding connection structure, the installation difficulty caused by the fixed position of the burner is solved, and the flexible adjustment of the burner position and the convenience of installation are realized.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHONGSHAN CUCINARTE INTELLIGENT KITCHEN CO LTD
- Filing Date
- 2025-05-07
- Publication Date
- 2026-06-05
AI Technical Summary
The burner position in existing gas stoves is fixed and cannot be adjusted according to user needs, making installation difficult and laborious.
Each burner is equipped with an independent base shell, and the upper and lower shell structures and adjustment mechanisms that are connected by sliding vertically allow for flexible adjustment and independent installation of the burner position.
It enables flexible adjustment of the burner position, meets diverse installation needs of users, and makes the installation process more convenient and labor-saving.
Smart Images

Figure CN224327224U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of gas stove technology, and in particular to a gas stove. Background Technology
[0002] In existing technology, gas stoves typically include a control panel, a base, and multiple burners. All burners are fixedly mounted on the base. Then, mounting holes corresponding to the relative positions of each burner are made on the control panel, and finally, each burner is installed into its corresponding hole. In these gas stoves, because the burners are fixed to the base before leaving the factory, their relative positions are fixed. Therefore, when installing the burners onto the control panel, they can only be installed according to pre-set positions and cannot be changed or adjusted according to user needs. This fails to meet diverse user installation requirements and severely impacts the user experience. Furthermore, installing the burners onto the control panel requires manually lifting the base, which is difficult due to the multiple burners inside, making the installation of the gas stove quite laborious and challenging. Utility Model Content
[0003] This utility model aims to solve at least one of the technical problems existing in the prior art. To this end, this utility model proposes a gas stove that is easy to install and allows for flexible adjustment of the installation positions of each burner to meet the diverse installation needs of users.
[0004] A gas stove according to an embodiment of the present utility model includes: at least two burners; a panel with mounting holes corresponding to each burner; wherein each burner is equipped with an independent bottom shell, the burner is fixedly installed on the corresponding bottom shell and installed in the corresponding mounting hole from bottom to top, and all the bottom shells are located below the panel and abut against the panel upwards.
[0005] The gas stove according to the embodiments of this utility model has at least the following beneficial effects:
[0006] In the gas stove of this embodiment, each burner is equipped with an independent base shell. After the burner is fixedly installed to the corresponding base shell, the user can drill mounting holes for the burners at suitable positions on the panel as needed, and then install each burner into the corresponding mounting holes. This structure allows the user to flexibly adjust the installation position of each burner as needed, meeting diverse installation requirements. Furthermore, compared to the prior art where multiple burners are fixedly installed in the same base shell and simultaneously installed to the panel, the gas stove of this embodiment has each burner installed independently, making the installation process more convenient and labor-saving.
[0007] According to some embodiments of the present invention, the burner includes a burner head, and the bottom shell includes an upper shell and a lower shell arranged in a vertical direction. The upper shell is mounted on the panel and has a clearance hole, and the burner head is mounted on the lower shell and passes through the clearance hole upward. The upper shell and the lower shell are slidably connected in a vertical direction, and at least one set of adjustment structures is provided between the upper shell and the lower shell. The adjustment structures can lock or unlock the upper shell and the lower shell.
[0008] According to some embodiments of the present invention, the adjustment structure includes a locking member and a first adjustment part and a second adjustment part that are slidably connected. One of the first adjustment part and the second adjustment part is disposed on the side wall of the upper housing, and the other is disposed on the side wall of the lower housing. The first adjustment part has a sliding groove arranged in the vertical direction, and the second adjustment part is movably inserted through the sliding groove and can move up and down along the sliding groove. The locking member is installed between the first adjustment part and the second adjustment part and can lock or unlock the first adjustment part and the second adjustment part.
[0009] According to some embodiments of the present invention, the second adjustment part is provided with a locking hole, the locking member is movably inserted through the slide groove and threadedly installed in the locking hole, the locking member has a locking part at one end near the first adjustment part, and the locking part can press against the periphery of the slide groove away from the second adjustment part.
[0010] According to some embodiments of the present invention, the burner further includes a water receiving tray installed on the outer periphery of the burner head. The water receiving tray abuts against the upper edge of the mounting hole. A pressure plate is installed on the lower surface of the water receiving tray. The pressure plate is spaced apart from the upper housing. At least one fastener is installed between the pressure plate and the upper housing. The fastener passes through the pressure plate from top to bottom and is threaded onto the upper housing. The upper end of the fastener has an outwardly protruding pressure portion. The pressure portion can press down against the pressure plate and cause the pressure plate to cooperate with the upper housing to clamp the panel.
[0011] According to some embodiments of this utility model, the upper surface of the pressure plate is provided with a relief groove corresponding to the fastener, the bottom wall of the relief groove is provided with a connecting hole for the fastener to pass through, the pressure part is embedded in the relief groove and presses downward against the upper edge of the connecting hole, and the horizontal height of the upper end of the pressure part is lower than or equal to the horizontal height of the upper surface of the pressure plate; the lower surface of the water receiving tray is provided with an installation groove adapted to the pressure plate, the pressure plate is embedded in the installation groove and fits against the inner top wall of the installation groove, and the lower surface of the water receiving tray fits against the upper surface of the panel.
[0012] According to some embodiments of the present invention, the lower surface of the water receiving tray is also fitted with a sealing ring that can press against the upper surface of the panel.
[0013] According to some embodiments of the present invention, the burner further includes an air intake assembly, a support frame is installed on the lower housing, the support frame has a support plate spaced apart from the inner bottom wall of the lower housing, the burner head is installed on the support plate, the air intake assembly is installed on the lower housing and located below the support plate, the air intake assembly has a gas pipe extending to communicate with the burner head, and the air intake assembly also has an air intake connector extending to the outside of the lower housing.
[0014] According to some embodiments of the present invention, each of the burner's air inlet connectors passes through the bottom wall of the corresponding lower housing and extends downward to the lower part of the corresponding lower housing. All the air inlet connectors have an air inlet nozzle rotatably mounted at their lower ends. The lower end of the air inlet nozzle has an upwardly bent insertion portion. The air inlet nozzle can rotate horizontally relative to the air inlet structure and change the orientation of the insertion portion.
[0015] According to some embodiments of the present invention, each burner is further equipped with a control knob, all control knobs are installed at intervals on the panel, each group of air intake components has a gas valve for controlling the gas flow, the control knob is mechanically connected, electrically connected or wirelessly connected to the corresponding gas valve, and the control knob can control whether the gas valve works or not.
[0016] Additional aspects and advantages of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Attached Figure Description
[0017] The above and / or additional aspects and advantages of this utility model will become apparent and readily understood from the description of the embodiments taken in conjunction with the following drawings, in which:
[0018] Figure 1 This is a schematic diagram of a gas stove according to an embodiment of the present utility model;
[0019] Figure 2 This is a schematic diagram of the burner of a gas stove according to an embodiment of the present utility model;
[0020] Figure 3 This is an exploded view of the burner of the gas stove according to an embodiment of the present utility model;
[0021] Figure 4 This is a cross-sectional schematic diagram of a gas stove according to an embodiment of the present utility model;
[0022] Figure 5 This is another cross-sectional schematic diagram of the gas stove according to an embodiment of the present utility model;
[0023] Figure 6 for Figure 5 Enlarged view of point A in the middle;
[0024] Figure 7 for Figure 6 Enlarged diagram of point B in the middle.
[0025] Figure label:
[0026] Burner 100, burner head 110, air intake assembly 120, gas pipeline 121, air intake connector 122, air intake nozzle 123, plug part 124, water receiving tray 130, mounting groove 131, sealing ring 132, pressure plate 140, clearance groove 141, fastener 150, pressure part 151;
[0027] Bottom shell 200, upper shell 210, clearance hole 211, lower shell 220, adjustment structure 230, first adjustment part 240, slide groove 241, second adjustment part 250, locking hole 251, locking member 260, locking part 261, support frame 270, support plate 271;
[0028] Panel 300, control knob 310. Detailed Implementation
[0029] The embodiments of this utility model are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain this utility model, and should not be construed as limiting this utility model.
[0030] In the description of this utility model, it should be understood that the directional descriptions, such as up, down, front, back, left, right, etc., indicate the directional or positional relationship based on the directional or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0031] In the description of this utility model, "several" means one or more, "multiple" means two or more, "greater than," "less than," and "exceeding" are understood to exclude the stated number, while "above," "below," and "within" are understood to include the stated number. If "first" or "second" is used in the description, it is only for the purpose of distinguishing technical features and should not be construed as indicating or implying relative importance, or implicitly indicating the number of indicated technical features, or implicitly indicating the order of the indicated technical features.
[0032] In the description of this utility model, unless otherwise explicitly defined, terms such as "setting," "installation," and "connection" should be interpreted broadly, and those skilled in the art can reasonably determine the specific meaning of the above terms in this utility model in conjunction with the specific content of the technical solution.
[0033] Reference Figures 1 to 7 This utility model provides a gas stove, which includes three burners 100 and a panel 300. The panel 300 has mounting holes corresponding to each burner 100. Each burner 100 is equipped with an independent base shell 200. The burner 100 is fixedly installed in the corresponding base shell 200 and installed from bottom to top in the corresponding mounting hole. All base shells 200 are located below the panel 300 and abut against the panel 300 upwards.
[0034] In the gas stove of this embodiment, each burner 100 is equipped with an independent base shell 200. After the burner 100 is fixedly installed to the corresponding base shell 200, the user can, as needed, open mounting holes for installing the burner 100 at appropriate positions on the panel 300, and then install each burner 100 into the corresponding mounting holes. This structure allows the user to flexibly adjust the installation position of each burner 100 as needed, meeting diverse installation requirements. Furthermore, compared to the prior art where multiple burners 100 are fixedly installed in the same base shell 200 and simultaneously installed to the panel 300, in the gas stove of this embodiment, each burner 100 is installed independently, making the installation process more convenient and labor-saving.
[0035] It is understandable that the number of burners 100 mentioned above is three, which is only for... Figure 1 As an example, the number of burners 100 can be three, two, four, five, or more, and this invention does not specifically limit the number. Furthermore, the types of the burners 100 can be the same or different, and this invention does not specifically limit the number of burners.
[0036] Reference Figures 1 to 7 In some embodiments, the burner 100 includes a burner head 110, and the base shell 200 includes an upper shell 210 and a lower shell 220 arranged vertically. The upper shell 210 is mounted on the panel 300 and has a clearance hole 211. The burner head 110 is mounted on the lower shell 220 and extends upward through the clearance hole 211. The upper shell 210 and the lower shell 220 are slidably connected vertically, and four sets of adjustment structures 230 are provided between the upper shell 210 and the lower shell 220. The adjustment structures 230 can lock or unlock the upper shell 210 and the lower shell 220.
[0037] In the above structure, the bottom shell 200 is divided into an upper shell 210 and a lower shell 220 that are slidably connected, and an adjustment mechanism is provided between the upper shell 210 and the lower shell 220. Therefore, during installation, the burner head 110 can be inserted through the clearance hole 211 and the upper shell 210 fixed to the panel 300. Then, the relative position between the lower shell 220 and the upper shell 210 is adjusted using the adjustment mechanism, thereby pushing the lower shell 220 and moving the burner head 110 upwards through the mounting hole to the preset installation position. This makes the installation of the burner 100 more convenient and effortless. Furthermore, this structure allows each burner 100 in the gas stove to be adjusted independently, ensuring that each burner 100 is accurately installed and preventing individual burners 100 from being loosely installed.
[0038] It is understandable that the aforementioned adjustment structure 230 consists of four sets, which is only for... Figures 1 to 7 As an example, the number of adjustment structures 230 can be four, one, two, three, five or more, and this utility model does not specifically limit this.
[0039] Reference Figures 1 to 6 In some embodiments, the adjustment structure 230 includes a locking member 260 and a first adjustment part 240 and a second adjustment part 250 that are slidably connected. The first adjustment part 240 is disposed on the side wall of the upper housing 210, and the second adjustment part 250 is disposed on the side wall of the lower housing 220. The first adjustment part 240 has a sliding groove 241 arranged in the vertical direction. The second adjustment part 250 is movably disposed in the sliding groove 241 and can move up and down along the sliding groove 241. The locking member 260 is installed between the first adjustment part 240 and the second adjustment part 250 and can lock or unlock the first adjustment part 240 and the second adjustment part 250.
[0040] In the above structure, by setting the adjustment structure 230 as a locking member 260 and a first adjustment part 240 and a second adjustment part 250 that are slidably connected, when adjusting the position of the lower housing 220, the first adjustment part 240 and the second adjustment part 250 can be unlocked by the locking member 260 first, and the lower housing 220 can be pushed to move in the up and down direction so that the second adjustment part 250 moves along the slide groove 241. When the burner head 110 moves to the preset position, the first adjustment part 240 and the second adjustment part 250 are locked by the locking member 260, thereby fixing the burner head 110 to the panel 300. The structure is simple and the operation is flexible and convenient.
[0041] It is understandable that the first adjustment part 240 is located on the side wall of the upper housing 210, and the second adjustment part 250 is located on the side wall of the lower housing 220, which is only for... Figures 1 to 7This is one example. In addition, the first adjustment part 240 may be provided in the lower housing 220 and the second adjustment part 250 may be provided in the upper housing 210. This utility model does not specifically limit this.
[0042] Reference Figures 1 to 7 In some embodiments, the second adjustment part 250 has a locking hole 251, and the locking member 260 is movably inserted through the slide groove 241 and threadedly installed in the locking hole 251. The locking member 260 has a locking part 261 at one end near the first adjustment part 240, and the locking part 261 can press against the periphery of the slide groove 241 away from the second adjustment part 250.
[0043] By adopting the above structure, during adjustment, the locking member 260 can be inserted into the slide groove 241 and the locking hole 251 first, and then the lower housing 220 can be pushed up and down. After the lower housing 220 and the burner head 110 reach the preset installation position, the locking member 260 can be turned so that the locking part 261 at the end of the locking member 260 presses against the periphery of the slide groove 241. In this way, the position lock between the upper housing 210 and the lower housing 220 can be achieved. The structure is simple and the operation is convenient.
[0044] It is understood that the aforementioned locking element 260 may be a screw, bolt, or other structure, and this utility model does not specifically limit it in this regard.
[0045] Reference Figures 1 to 7 In some embodiments, the burner 100 further includes a water receiving tray 130 installed on the outer periphery of the burner head 110. The water receiving tray 130 abuts against the upper edge of the mounting hole, and a pressure plate 140 is installed on the lower surface of the water receiving tray 130. The pressure plate 140 is spaced apart from the upper housing 210. At least one fastener 150 is installed between the pressure plate 140 and the upper housing 210. The fastener 150 passes through the pressure plate 140 from top to bottom and is threaded onto the upper housing 210. The upper end of the fastener 150 has an outwardly protruding pressure portion 151. The pressure portion 151 can press down against the pressure plate 140 and make the pressure plate 140 and the upper housing 210 cooperate to clamp the panel 300.
[0046] By adopting the above structure, the water tray 130 can prevent liquid from flowing downward into the mounting hole and into the bottom shell 200 during use. The pressure plate 140 facilitates the installation and fixation of the water tray 130. By installing fasteners 150 on the pressure plate 140, the fasteners 150 pass through the pressure plate 140 from top to bottom and are threaded onto the upper shell 210. The panel 300 is sandwiched between the pressure plate 140 and the upper shell 210, so that the pressure plate 140 and the upper shell 210 can cooperate to clamp the panel 300, thereby enabling the installation and fixation of the water tray 130, the panel 300 and the bottom shell 200, making the gas stove structure more robust and stable.
[0047] It is understood that the upper housing 210 is mounted on the panel 300. Specifically, the upper housing 210 can be directly mounted on the pressure plate 140 by fasteners 150 to fix it to the panel 300, or an additional connecting piece can be provided between the upper housing 210 and the panel 300. This utility model does not make any specific limitations on this.
[0048] It is understandable that the fastener 150 is inserted through the pressure plate 140 from top to bottom and threaded onto the upper housing 210. Specifically, the fastener 150 can be inserted through the pressure plate 140 and the panel 300 from top to bottom and threaded onto the upper housing 210, thereby making the connection between the pressure plate 140, the panel 300 and the bottom housing 200 more secure. Alternatively, the fastener 150 can be located at the mounting hole, that is, the fastener 150 is directly inserted through the pressure plate 140 from top to bottom and threaded onto the upper housing 210. By tightening the fastener 150, the pressure plate 140 and the upper housing 210 move relative to each other and clamp the panel 300, thereby achieving the connection between the pressure plate 140, the panel 300 and the bottom housing 200.
[0049] Reference Figures 1 to 7 In some embodiments, the upper surface of the pressure plate 140 is provided with a relief groove 141 corresponding to the fastener 150. The bottom wall of the relief groove 141 is provided with a connecting hole for the fastener 150 to pass through. The pressure part 151 is embedded in the relief groove 141 and presses downward against the upper edge of the connecting hole. The horizontal height of the upper end of the pressure part 151 is lower than or equal to the horizontal height of the upper surface of the pressure plate 140. The lower surface of the water receiving tray 130 is provided with a mounting groove 131 adapted to the pressure plate 140. The pressure plate 140 is embedded in the mounting groove 131 and fits against the inner top wall of the mounting groove 131. The lower surface of the water receiving tray 130 fits against the upper surface of the panel 300.
[0050] By adopting the above structure, the pressure plate 140 is embedded in the mounting groove 131 on the lower surface of the water receiving tray 130, thereby ensuring the flatness of the lower surface of the water receiving tray 130, so as to facilitate the lower surface of the water receiving tray 130 to fit against the panel 300. In addition, by opening a relief groove 141 on the upper surface of the pressure plate 140, the pressure part 151 of the fastener 150 can be embedded in the relief groove 141 without protruding upward from the pressure plate 140, thereby allowing the upper surface of the pressure plate 140 to fit against the inner top wall of the mounting groove 131, and thus making the connection between the pressure plate 140 and the water receiving tray 130 more stable.
[0051] Reference Figures 4 to 7In some embodiments, the lower surface of the water receiving tray 130 is also fitted with a sealing ring 132 that can press against the upper surface of the panel 300, thereby enabling the water receiving tray 130 to be tightly connected to the upper surface of the panel 300, further reducing the risk of external liquid flowing from the gap between the water receiving tray 130 and the panel 300 to the mounting hole, thus ensuring the normal operation of the burner 100.
[0052] Reference Figures 1 to 5 In some embodiments, the burner 100 further includes an air intake assembly 120, a support frame 270 is mounted on the lower housing 220, the support frame 270 has a support plate 271 spaced apart from the inner bottom wall of the lower housing 220, the burner head 110 is mounted on the support plate 271, the air intake assembly 120 is mounted on the lower housing 220 and located below the support plate 271, the air intake assembly 120 has a gas pipe 121 extending to communicate with the burner head 110, and the air intake assembly 120 also has an air intake connector 122 extending to the outside of the lower housing 220.
[0053] By adopting the above structure, the support frame 270 can provide support for the installation of the burner head 110 and facilitate the installation layout between the burner head 110 and the air intake assembly 120 inside the bottom shell 200, making reasonable use of the internal space of the bottom shell 200, and making the structure of the burner 100 more compact and stable.
[0054] Reference Figures 1 to 5 In some embodiments, the air inlet connector 122 of each burner 100 passes through the bottom wall of the corresponding lower housing 220 and extends downward to the lower part of the corresponding lower housing 220. The lower end of all air inlet connectors 122 is rotatably mounted with an air inlet nozzle 123. The lower end of the air inlet nozzle 123 has an upwardly bent insertion portion 124. The air inlet nozzle 123 can rotate horizontally relative to the air inlet structure and change the orientation of the insertion portion 124.
[0055] By adopting the above structure, the air inlet connector 122 extends to the lower side of the bottom shell 200, thereby connecting with an external gas transmission pipe to realize gas transmission. In particular, by rotatably mounting the air inlet nozzle 123 on the air inlet connector 122, when connecting the air inlet connector 122 to the external gas transmission pipe, the air inlet nozzle 123 can be flexibly rotated according to the position of the external gas transmission pipe to adjust the orientation of the insertion part 124, so that the insertion part 124 can face the gas outlet of the external gas transmission pipe, thereby facilitating the connection between the air inlet connector 122 and the external gas transmission pipe.
[0056] Understandably, the external gas supply pipe can be equipped with multiple gas outlet joints, which can conveniently supply gas to multiple burners 100 on the gas stove.
[0057] Reference Figure 1In some embodiments, each burner 100 is also equipped with a control knob 310. All control knobs 310 are spaced apart on the panel 300. Each group of air intake components 120 has a gas valve for controlling the gas flow. The control knob 310 is mechanically, electrically, or wirelessly connected to the corresponding gas valve, and the control knob 310 can control whether the gas valve is working or not.
[0058] By adopting the above structure, and equipping each burner 100 with a control knob 310, the gas flow rate and flame intensity of each burner 100 can be independently controlled, which improves the user experience. The control knob 310 can be mechanically connected to the gas valve of the air intake assembly 120, thereby mechanically controlling the opening and closing of the gas valve to regulate the gas flow rate. Alternatively, the control knob 310 can be electrically connected to the gas valve of the air intake assembly 120. In this case, not only can the opening and closing of the gas valve be controlled by the control knob 310, but the control knob 310 can also be installed in a suitable position as needed. The burner 100 does not restrict the installation position of the control knob 310, making its installation more flexible. Furthermore, the control knob 310 can also be wirelessly connected to the gas valve of the air intake assembly 120, such as via Bluetooth or Wi-Fi, thus allowing for flexible adjustment of its installation position.
[0059] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.
Claims
1. A gas stove, characterized in that, include: At least two burners (100); The panel (300) has mounting holes corresponding to each of the burners (100); Each burner (100) is equipped with an independent bottom shell (200). The burner (100) is fixedly installed on the corresponding bottom shell (200) and installed in the corresponding mounting hole from bottom to top. All the bottom shells (200) are located below the panel (300) and abut against the panel (300) upwards.
2. The gas stove according to claim 1, characterized in that, The burner (100) includes a burner head (110), and the bottom shell (200) includes an upper shell (210) and a lower shell (220) arranged in a vertical direction. The upper shell (210) is mounted on the panel (300) and has a clearance hole (211). The burner head (110) is mounted on the lower shell (220) and extends upward through the clearance hole (211). The upper housing (210) and the lower housing (220) are slidably connected in the vertical direction, and at least one set of adjustment structure (230) is provided between the upper housing (210) and the lower housing (220), the adjustment structure (230) being able to lock or unlock the upper housing (210) and the lower housing (220).
3. The gas stove according to claim 2, characterized in that, The adjustment structure (230) includes a locking member (260) and a first adjustment part (240) and a second adjustment part (250) that are slidably connected. One of the first adjustment part (240) and the second adjustment part (250) is provided on the side wall of the upper housing (210), and the other is provided on the side wall of the lower housing (220). The first adjustment part (240) has a slide groove (241) arranged in the vertical direction. The second adjustment part (250) is movably inserted through the slide groove (241) and can move up and down along the slide groove (241). The locking member (260) is installed between the first adjustment part (240) and the second adjustment part (250) and can lock or unlock the first adjustment part (240) and the second adjustment part (250).
4. The gas stove according to claim 3, characterized in that, The second adjustment part (250) has a locking hole (251). The locking member (260) is movably inserted through the slide groove (241) and threaded into the locking hole (251). The locking member (260) has a locking part (261) at one end near the first adjustment part (240). The locking part (261) can press against the periphery of the slide groove (241) away from the second adjustment part (250).
5. The gas stove according to claim 4, characterized in that, The burner (100) also includes a water receiving tray (130) installed on the outer periphery of the burner head (110). The water receiving tray (130) abuts against the upper edge of the mounting hole. A pressure plate (140) is installed on the lower surface of the water receiving tray (130). The pressure plate (140) is spaced apart from the upper housing (210). At least one fastener (150) is installed between the pressure plate (140) and the upper housing (210). The fastener (150) passes through the pressure plate (140) from top to bottom and is threaded onto the upper housing (210). The upper end of the fastener (150) has an outwardly protruding pressure portion (151). The pressure portion (151) can press down against the pressure plate (140) and make the pressure plate (140) and the upper housing (210) cooperate to clamp the panel (300).
6. The gas stove according to claim 5, characterized in that, The upper surface of the pressure plate (140) is provided with a relief groove (141) corresponding to the fastener (150). The bottom wall of the relief groove (141) is provided with a connecting hole for the fastener (150) to pass through. The pressing part (151) is embedded in the relief groove (141) and presses downward against the upper edge of the connecting hole. The horizontal height of the upper end of the pressing part (151) is lower than or equal to the horizontal height of the upper surface of the pressure plate (140). The lower surface of the water receiving tray (130) is provided with an installation groove (131) that is adapted to the pressure plate (140). The pressure plate (140) is embedded in the installation groove (131) and is in contact with the inner top wall of the installation groove (131). The lower surface of the water receiving tray (130) is in contact with the upper surface of the panel (300).
7. The gas stove according to claim 5, characterized in that, The lower surface of the water receiving tray (130) is also fitted with a sealing ring (132) that can press against the upper surface of the panel (300).
8. The gas stove according to claim 2, characterized in that, The burner (100) further includes an air intake assembly (120), the lower housing (220) is equipped with a support frame (270), the support frame (270) has a support plate (271) spaced apart from the inner bottom wall of the lower housing (220), the burner head (110) is mounted on the support plate (271), the air intake assembly (120) is mounted on the lower housing (220) and located below the support plate (271), the air intake assembly (120) has a gas pipe (121) extending to communicate with the burner head (110), and the air intake assembly (120) also has an air intake connector (122) extending to the outside of the lower housing (220).
9. The gas stove according to claim 8, characterized in that, Each of the burners (100) has an air inlet connector (122) that passes through the bottom wall of the corresponding lower housing (220) and extends downward to the bottom of the corresponding lower housing (220). All the air inlets (122) have an air inlet nozzle (123) rotatably mounted on their lower ends. The lower end of the air inlet nozzle (123) has an upwardly bent insertion portion (124). The air inlet nozzle (123) can rotate horizontally relative to the air inlet structure and change the orientation of the insertion portion (124).
10. The gas stove according to claim 8, characterized in that, Each burner (100) is also equipped with a control knob (310), all of which are spaced apart on the panel (300). Each group of air intake assemblies (120) has a gas valve for controlling the gas flow rate. The control knob (310) is mechanically, electrically, or wirelessly connected to the corresponding gas valve, and the control knob (310) can control whether the gas valve is working.