CN217843971U - Gas kitchen ranges - Google Patents
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- CN217843971U CN217843971U CN202221769402.4U CN202221769402U CN217843971U CN 217843971 U CN217843971 U CN 217843971U CN 202221769402 U CN202221769402 U CN 202221769402U CN 217843971 U CN217843971 U CN 217843971U
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Abstract
The utility model provides a gas stove, which belongs to the technical field of cooking utensils. The gas stove comprises a gas valve fixing seat, a stir-frying pipeline, an inner ring pipeline, an outer ring pipeline and a stove head, wherein the gas valve fixing seat is provided with a gas inner cavity, a gas inlet, a stir-frying gas outlet and gas outlets of the inner ring pipeline and the outer ring pipeline; the burner is provided with an air outlet cavity, a gas inlet is communicated with the air outlet cavity through a gas inner cavity, a quick-frying gas outlet and a quick-frying pipeline in sequence, the gas inlet is communicated with the air outlet cavity through the gas inner cavity, an inner and outer ring pipeline air outlet and an inner ring pipeline in sequence, and the gas inlet is communicated with the air outlet cavity through the gas inner cavity, the inner and outer ring pipeline air outlet and an outer ring pipeline in sequence; the control valve is used for controlling the flow of fuel gas entering the gas outlet cavity through the stir-frying pipeline. The utility model discloses a gas-cooker for load to exploding the stir-fry is adjusted, in order to satisfy user's firepower demand.
Description
Technical Field
The utility model relates to a cooking utensils technical field, in particular to gas-cooker.
Background
Quick-frying is an important cooking mode in delicious food, and a gas stove is required to provide a fierce fire during quick-frying so as to meet the needs of users.
However, in the stir-frying technology in the current industry, the stir-frying is usually realized by increasing the flow rate of the fuel gas of the inner ring of the burner or the outer ring of the burner, and since the stir-frying is realized by intercepting the fuel gas by an electromagnetic valve in the pipeline (or called inner ring pipeline) corresponding to the inner ring of the burner or the pipeline (or called inner ring pipeline) corresponding to the outer ring of the burner, the load of the stir-frying is often only one, and cannot be adjusted, so that the required fire demand cannot be met when different food materials are cooked.
SUMMERY OF THE UTILITY MODEL
The utility model aims at providing a gas stove for load to exploding the stir-fry is adjusted, in order to satisfy user's firepower demand.
The above object of the present invention can be achieved by the following technical solutions:
the utility model provides a gas stove, include:
the gas valve fixing seat is provided with a gas inner cavity, a gas inlet, a stir-frying gas outlet and an inner and outer ring pipeline gas outlet;
a stir-frying pipeline;
an inner loop pipeline;
an outer ring pipeline;
the burner is provided with an air outlet cavity, a gas inlet is communicated with the air outlet cavity through a gas inner cavity, a quick-frying gas outlet and a quick-frying pipeline in sequence, the gas inlet is communicated with the air outlet cavity through the gas inner cavity, an inner and outer ring pipeline air outlet and an inner ring pipeline in sequence, and the gas inlet is communicated with the air outlet cavity through the gas inner cavity, the inner and outer ring pipeline air outlet and an outer ring pipeline in sequence;
and the control valve is used for controlling the flow of the fuel gas entering the gas outlet cavity through the stir-frying pipeline.
The utility model discloses an among the embodiment, the control valve includes the motor valve, sets up in stir-fry gas outlet department.
In an embodiment of the present invention, the motor valve includes:
the rotation driving motor is arranged at the installation opening of the rotation driving motor of the air valve fixing seat;
the case, set up in the gas inner chamber and be located stir-fry gas outlet department, and the case is connected and is rotated driving motor, wherein, the case has the case chamber of admitting air, the case is equipped with a plurality of load regulation passageways of stir-fry that explode along its circumference interval, a plurality of load regulation passageways of stir-fry intercommunication case chamber of admitting air, when rotating driving motor and rotating and driving the case and rotate, a plurality of load regulation passageways of stir-fry that explode of case are corresponding to stir-fry gas outlet respectively, a plurality of load regulation passageways of stir-fry that explode are configured to through stir-fry gas outlet different displacement to stir-fry pipeline to stir-fry.
In the embodiment of the utility model, the number of the stir-fry load adjusting channels is five, which are respectively a first stir-fry load adjusting channel, a second stir-fry load adjusting channel, a third stir-fry load adjusting channel, a fourth stir-fry load adjusting channel and a fifth stir-fry load adjusting channel which are arranged in sequence, wherein,
the first stir-frying load adjusting channel is communicated with the valve core air inlet cavity;
the second stir-frying load adjusting channel is communicated with the valve core air inlet cavity;
a first communicating channel is arranged between the second stir-frying load adjusting channel and the third stir-frying load adjusting channel, and the third stir-frying load adjusting channel is communicated with the valve core air inlet cavity through the first communicating channel and the second stir-frying load adjusting channel in sequence;
a second communicating channel is arranged between the third stir-frying load adjusting channel and the fourth stir-frying load adjusting channel, and the fourth stir-frying load adjusting channel is communicated with the valve core air inlet cavity through the second communicating channel, the third stir-frying load adjusting channel, the first communicating channel and the second stir-frying load adjusting channel in sequence;
a third communicating channel is arranged between the fourth stir-frying load adjusting channel and the fifth stir-frying load adjusting channel, and the fifth stir-frying load adjusting channel is communicated with the valve core air inlet cavity through the third communicating channel, the fourth stir-frying load adjusting channel, the second communicating channel, the third stir-frying load adjusting channel, the first communicating channel and the second stir-frying load adjusting channel in sequence.
In the embodiment of the present invention, the first explosion load adjusting passage has an inner diameter D 1 The inner diameter of the second stir-frying load adjusting channel is D 2 The first communicating passage has an inner diameter D 3 And the inner diameter of the second communicating passage is D 4 And the third communicating path has an inner diameter D 5 Then there is, D 1 >D 2 >D 3 >D 4 >D 5 。
In the embodiment of the utility model, the utility model also comprises a controller which is electrically connected with the rotation driving motor and is used for controlling the rotation driving motor to rotate according to the first data of the pot on the furnace end; wherein the content of the first and second substances,
the first data is indicative of temperature.
The utility model discloses an in the embodiment, still include temperature sensor, electric connection controller just is used for detecting first data.
The utility model discloses an among the embodiment, go out the air cavity and include outer loop air cavity and inner ring air cavity, the gas inner chamber loops through to explode to fry the gas outlet, explode to fry pipeline intercommunication outer loop air cavity and/or inner ring air cavity.
The utility model discloses an among the embodiment, still include solenoid valve and plug valve, the solenoid valve sets up in gas inlet department, and the plug valve sets up in interior outer loop pipeline gas outlet department, and outer loop pipeline and inner loop pipeline all set up in plug valve and parallel breather valve fixing base.
In the embodiment of the present invention, the outer ring pipeline is connected to the outer ring air chamber, and the inner ring pipeline is connected to the inner ring air chamber of the furnace end.
The utility model has the characteristics and advantages that:
the utility model discloses a gas-cooker explodes to fry is not gone on through damming in inner ring pipeline or outer loop pipeline, but goes on through setting up in an individual pipeline of pneumatic valve fixing base (explode to fry the pipeline) to, can control through the control valve explode the flow of the gas that fries the pipeline and get into the play air cavity of furnace end, from this, can adjust the load of exploding to fry through the flow that changes the gas, in order to satisfy user's firepower demand.
Drawings
The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings.
Fig. 1 is a schematic perspective view of a gas range of the present invention;
FIG. 2 is a schematic perspective view of the valve fixing seat and the control valve of the present invention;
FIG. 3 is an exploded view of the valve fixing base and the control valve of the present invention;
fig. 4 is a schematic perspective view of the valve core of the present invention;
fig. 5 is a schematic connection diagram of the valve core in the main view direction of the present invention;
FIG. 6 isbase:Sub>A cross-sectional view taken along A-A of FIG. 5;
fig. 7 is a schematic diagram of the rotation driving motor, the controller and the temperature sensor according to the present invention.
Reference numerals and description:
1. an air valve fixing seat; 11. a gas inner cavity; 12. a gas inlet; 13. a gas outlet for quick-frying fuel gas; 14. air outlets of the inner and outer ring pipelines;
2. a stir-frying pipeline;
3. an inner loop pipeline;
4. an outer ring pipeline;
5. a furnace end;
6. a control valve; 61. rotating the drive motor; 62. a valve core; 621. a valve core air inlet cavity; 622. a stir-frying load adjusting channel; 6221. a first stir-fry load adjustment channel; 6222. a second stir-frying load adjusting channel; 6223. a third stir-frying load adjusting channel; 6224. a fourth stir-frying load adjusting channel; 6225. a fifth stir-frying load adjusting channel; 6226. a first communicating passage; 6227. a second communicating passage; 6228. a third communicating passage;
7. a controller;
8. a temperature sensor;
9. an electromagnetic valve;
10. a plug valve.
Detailed Description
Example embodiments will now be described more fully with reference to the accompanying drawings. Example embodiments may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of example embodiments to those skilled in the art. The same reference numerals in the drawings denote the same or similar structures, and thus their detailed description will be omitted.
The terms "a", "an", "the", "said" are used to indicate the presence of one or more elements/components/etc.; the terms "comprising" and "having" are intended to be inclusive and mean that there may be additional elements/components/etc. other than the listed elements/components/etc.
As shown in fig. 1 to 7, the utility model provides a gas stove, which comprises a gas valve fixing seat 1, an explosion-frying pipeline 2, an inner ring pipeline 3, an outer ring pipeline 4 and a furnace end 5, wherein the gas valve fixing seat 1 is provided with a gas inner cavity 11, a gas inlet 12, an explosion-frying gas outlet 13 and an inner ring pipeline and outer ring pipeline gas outlet 14; the burner 5 is provided with an air outlet cavity, a gas inlet 12 is communicated with the air outlet cavity through a gas inner cavity 11, a quick-frying gas outlet 13 and a quick-frying pipeline 2 in sequence, the gas inlet 12 is communicated with the air outlet cavity through the gas inner cavity 11, an inner and outer ring pipeline air outlet 14 and an inner ring pipeline 3 in sequence, the gas inlet 12 is communicated with the air outlet cavity through the gas inner cavity 11, the inner and outer ring pipeline air outlet 14 and an outer ring pipeline 4 in sequence, namely, the gas can enter the air outlet cavity of the burner 5 through the inner ring pipeline 3, the outer ring pipeline 4 and the quick-frying pipeline 2 respectively; the control valve 6 is used for controlling the flow of the fuel gas entering the gas outlet cavity from the stir-frying pipeline 2.
The utility model discloses a gas-cooker explodes to fry and does not go on through damming in inner ring pipeline 3 or outer loop pipeline 4, but goes on through setting up in an individual pipeline of pneumatic valve fixing base 1 (explode to fry pipeline 2) to, can control through control valve 6 explode the flow of the gas of stir-fry pipeline 2 entering furnace end 5's the play air cavity, from this, can adjust the load of exploding to fry through the flow that changes the gas, in order to satisfy user's firepower demand.
In concrete application, air valve fixing base 1 can be equivalent to three-way pipe fitting, and three mouthful of three-way pipe fitting can correspond to gas air inlet 12, explode stir-fry gas outlet 13 and interior outer ring pipeline gas outlet 14, from this, still can be convenient for communicate the gas pipe through setting up air valve fixing base 1, reduces the installation degree of difficulty of gas-cooker, also, the tip lug connection of gas pipe is in gas air inlet 12, can realize the gas supply to outer loop pipeline 4, inner ring pipeline 3 and stir-fry pipeline 2.
Specifically, go out the air cavity and include outer loop air cavity and inner ring air cavity, gas inner chamber 11 loops through explode to fry gas outlet 13, explode to fry 2 intercommunication outer loop air cavities of pipeline and/or inner ring air cavities, promptly, the gas in the gas inner chamber 11 is through exploding to fry 2 backs of pipeline, both can flow to outer loop air cavity, can flow to inner ring air cavity again, can also flow to outer loop air cavity and inner ring air cavity simultaneously to further satisfy user's firepower demand.
In this embodiment, as shown in fig. 2 and fig. 3, the gas stove may further include an electromagnetic valve 9 and a plug valve 10, the electromagnetic valve 9 is disposed at a gas inlet 12, the plug valve 10 is disposed at an air outlet 14 of the inner and outer annular pipelines, and both the outer annular pipeline 4 and the inner annular pipeline 3 are disposed at the plug valve 10 and connected to the vent valve fixing seat 1, in a specific application, when the electromagnetic valve 9 is opened, gas enters the gas stove (the gas valve fixing seat 1), the size of the opening of the plug valve 10 is controlled by adjusting the plug valve 10 to control the gas flow rate of the outer annular pipeline 4 and the inner annular pipeline 3 flowing into the gas inner cavity 11, so as to achieve normal (non-explosion mode) fire regulation, when a user needs explosion, the control valve 6 is opened to control the gas flow rate of the explosion-frying pipeline 2 entering the air outlet cavity, so that the stove enters the explosion-frying mode, and as the opening of the control valve 6 increases, the explosion-frying load also increases, and when the control valve 6 is closed, the explosion-frying mode ends.
Further, the outer ring pipeline 4 can be communicated with an outer ring air cavity, the inner ring pipeline 3 can be communicated with an inner ring air cavity of the furnace end 5, in specific application, the outer ring air cavity corresponds to outer ring fire, the inner ring air cavity corresponds to inner ring fire, and if only the outer ring fire does not have the inner ring fire, the result is that the heat center of the outer ring of the boiler is a heating blind area; if only the inner ring fire does not have the outer ring fire, the firepower does not reach the big fire, and the cooking is too slow; as for the middle ring fire (or called middle ring fire), the middle ring fire is unnecessary if the inner ring fire is designed reasonably, because the middle ring fire tends to "interfere" with the inner ring fire, resulting in an increase in exhaust emissions.
The utility model discloses an in an embodiment, control valve 6 can include the motor valve, sets up in exploding 13 departments of stir-fry gas outlet to through setting up the motor valve, so that the control explodes the flow of stir-fry pipeline 2 and get into the gas in the play air cavity of furnace end 5.
Specifically, as shown in fig. 2 to 6, the motor valve may include a rotation driving motor 61 and a valve core 62, the rotation driving motor 61 is disposed at a rotation driving motor mounting opening of the air valve fixing seat 1, the rotation driving motor 61 may be a stepping motor to reduce deviation of a control angle, the valve core 62 is disposed in the gas inner cavity 11 and located at the explosion-stir-frying gas outlet 13, and the valve core 62 is connected to the rotation driving motor 61, wherein the valve core 62 has a valve core inlet cavity 621, the valve core 62 is circumferentially provided with a plurality of explosion-stir-frying load adjusting channels 622 at intervals, the plurality of explosion-stir-frying load adjusting channels 622 are communicated with the valve core inlet cavity 621, when the rotation driving motor 61 rotates the valve core 62, the plurality of explosion-stir-frying load adjusting channels 622 of the valve core 62 respectively correspond to the explosion-stir-frying gas outlet 13, a plurality of load regulation passageways 622 that fry that explode are configured as through the different air displacement of frying gas outlet 13 discharge to frying pipeline 2 that explode, in concrete application, because a plurality of load regulation passageways 622 that fry that explode of the circumference of case 62 correspond different load sizes, that is, a plurality of load regulation passageways 622 that fry that explode correspond different firepower of frying and keep off the position, therefore, when rotating driving motor 61 and rotating, can drive case 62 and rotate, the intercommunication of frying pipeline 2 and gas inner chamber 11 is realized frying through the load regulation passageway 622 that explode on the case 62, so that the control explodes the flow of the gas that fries pipeline 2 and get into gas inner chamber 11, be convenient for adjust the load of frying, satisfy user's firepower demand.
In this embodiment, as shown in fig. 4 to 6, the number of the burst load adjusting passages 622 may be five, and the number of the burst load adjusting passages is a first burst load adjusting passage 6221, a second burst load adjusting passage 6222, a third burst load adjusting passage 6223, a fourth burst load adjusting passage 6224 and a fifth burst load adjusting passage 6225 which are sequentially arranged, wherein the first burst load adjusting passage 6221 is communicated with the valve core air inlet cavity 621; the second stir-frying load adjusting passage 6222 is communicated with the valve core air inlet cavity 621; a first communicating channel 6226 is arranged between the second quick-frying load adjusting channel 6222 and the third quick-frying load adjusting channel 6223, and the third quick-frying load adjusting channel 6223 is communicated with the valve core air inlet cavity 621 through the first communicating channel 6226 and the second quick-frying load adjusting channel 6222 in sequence; a second communication channel 6227 is arranged between the third burst load adjusting channel 6223 and the fourth burst load adjusting channel 6224, and the fourth burst load adjusting channel 6224 is communicated with the valve core air inlet cavity 621 through the second communication channel 6227, the third burst load adjusting channel 6223, the first communication channel 6226 and the second burst load adjusting channel 6222 in sequence; a third communication channel 6228 is arranged between the fourth burst load adjusting channel 6224 and the fifth burst load adjusting channel 6225, and the fifth burst load adjusting channel 6225 is communicated with the valve core air inlet cavity 621 through the third communication channel 6228, the fourth burst load adjusting channel 6224, the second communication channel 6227, the third burst load adjusting channel 6223, the first communication channel 6226 and the second burst load adjusting channel 6222 in sequence.
In some embodiments, the stir load adjustment channel 622 can also be three, six, eight, or more in number.
Specifically, the first burst load adjustment passage 6221 has an inner diameter D 1 The inner diameter of the second stir-fry load adjusting passage 6222 is D 2 The first communicating passage 6226 has an inner diameter D 3 And the second communicating path 6227 has an inner diameter D 4 And the third communicating passage 6228 has an inner diameter D 5 Then there is, D 1 >D 2 >D 3 >D 4 >D 5 In a specific application, when the valve core 62 rotates 40 degrees to discharge gas from the first burst load adjusting passage 6221, a first gear (maximum burst fire power) can be corresponded, when the valve core 62 rotates 80 degrees to discharge gas from the second burst load adjusting passage 6222, a second gear can be corresponded, when the valve core 62 rotates 120 degrees to discharge gas from the third burst load adjusting passage 6223,the valve core 62 can correspond to a third gear, when the valve core 62 rotates 160 degrees to enable the fourth quick-frying load adjusting channel 6224 to discharge gas, the valve core can correspond to a fourth gear, and when the valve core 62 rotates 200 degrees to enable the fifth quick-frying load adjusting channel 6225 to discharge gas, the valve core can correspond to a fifth gear (minimum quick-frying firepower), the function of sectional quick-frying is achieved, and the firepower requirement of a user is further met.
In some embodiments, the first communicating passage 6226, the second communicating passage 6227 and the third communicating passage 6228 may not be provided, that is, each of the explosion load adjusting passages 622 may be directly communicated with the valve core air inlet chamber 621 of the valve core 62, and the explosion load adjusting passages 622 may also be adjusted, but because the explosion load adjusting passages 622 are provided along the circumferential direction of the valve core 62, if the number of the explosion load adjusting passages 622 is too large (for example, eight) or the outer diameter of the valve core 62 is small, the distance between the adjacent explosion load adjusting passages 622 is relatively short, therefore, when the rotation driving motor 61 drives the valve core 62 to rotate, so that the adjacent explosion load adjusting passages 622 of the valve core 62 face the explosion gas outlet 13, for example, if the user wants to reduce the fire power, the fire power is reduced from the second fire power to the third fire power, the valve core 62 is driven to rotate along with the rotation driving motor 61, when the second explosion load adjusting passage 6222 and the third explosion load adjusting passage 6223 face the explosion gas outlet 13, the valve core 62 rotates by 80 degrees to 120 degrees, the gas flows through the second communicating passage 6211, and the explosion load adjusting passages are respectively larger than the second explosion load adjusting passages 6222, thereby not only satisfying the condition that the condition of the non-linear fire power adjustment of the explosion load adjustment can be met, but the condition that the non-explosion load adjustment of the non-linear fire power adjustment pipeline exists.
In some embodiments, the cross-sections of the first, second, third, fourth, fifth, and third burst load adjustment passages 6221, 6222, 6223, 6224, 6225, 6226, 6227, 6228 can all be circular, and D can be circular, or can be circular 1 Can adjust the minimum inner diameter, D, of the passage 6221 for the first stir-fry load 2 The minimum inner diameter, D, of the passage 6222 can be adjusted for the second stir-fry load 3 Can be the firstAn inner diameter, D, of a communication passage 6226 4 May be the smallest inner diameter, D, of the second communication passage 6227 5 May be the smallest inner diameter of the third communication passage 6228.
Further, the second stir-fry load adjusting passage 6222 may include a pressure stabilizing hole, a diffusion hole and a through hole which are connected in sequence and have sequentially increased aperture in the radial outward direction of the valve core 62, and the pressure stabilizing hole extends in the radial direction of the valve core 62 to perform a pressure reducing function, so that the flame of the burner 5 is not easy to shake, and the combustion is more uniform; the diffusion holes are gradually expanded along the radial outward direction of the valve core 62, so that the gas diffusion is more uniform, and the function of transition gas pressure is achieved; the shape of the through hole is matched with the shape of the stir-frying pipeline 2, so that the air flow impact caused by the fuel gas in the valve core 62 on the stir-frying pipeline 2 when flowing out is reduced, the joint of the air valve fixing seat 1 and the stir-frying pipeline 2 is not easy to leak, and in addition, the pressure loss can be reduced.
In specific application, the valve core 62 can be in a column shape, and the smaller the diameter of the valve core is along the radial direction of the valve core, if the first burst stir-frying load adjusting channel 6221, the second burst stir-frying load adjusting channel 6222, the third burst stir-frying load adjusting channel 6223, the fourth burst stir-frying load adjusting channel 6224 and the fifth burst stir-frying load adjusting channel 6225 are all provided with through holes, the area of the peripheral wall of the valve core air inlet cavity 621 is smaller, the number of the burst stir-frying load adjusting channels on the valve core 62 is not easy to be too large, the load adjusting range is limited, and the requirement of a user on burst stir-frying firepower cannot be further met.
Furthermore, as shown in fig. 7, the gas stove of the present invention may further include a controller 7 electrically connected to the rotation driving motor 61 for controlling the rotation driving motor 61 to rotate according to the first data of the pot on the burner 5; wherein, first data sign temperature, the utility model discloses a gas-cooker still can include temperature sensor 8, and electric connection controller 7 just is used for detecting first data.
Through the structural arrangement, the rotation of the driving motor is controlled conveniently according to the temperature of the pan, so that the quick frying is automatically realized, for example, when the temperature of the pan is lower than a preset value, the controller 7 controls the rotation of the driving motor 61 to drive the valve core 62 to rotate, so that the quick frying load adjusting channel 622 of the valve core 62 is aligned to the quick frying gas outlet 13, and the gas in the gas inner cavity 11 flows to the gas outlet cavity of the burner 5, so that the quick frying is realized; when the temperature of the pan is higher than the preset value, the controller 7 controls the rotation driving motor 61 to rotate to drive the valve core 62 to rotate, so that the stir-frying load adjusting channel 622 of the valve core 62 is not aligned with the stir-frying gas outlet 13 or is shifted up (for example, shifted from a first shift to a fifth shift) to prohibit or reduce the gas in the gas inner cavity 11 from flowing to the gas outlet cavity of the burner 5, thereby reducing the load value.
In the embodiments of the present invention, the term "plurality" means two or more unless explicitly defined otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral connections. The specific meaning of the above terms in the embodiments of the present invention can be understood by those of ordinary skill in the art according to specific situations.
In the description of the embodiments of the present invention, it should be understood that the terms "upper" and "lower" are used for indicating the position or the positional relationship based on the position or the positional relationship shown in the drawings, and are only for convenience of describing the embodiments of the present invention and simplifying the description, but not for indicating or implying that the indicated device or unit must have a specific direction, be constructed and operated in a specific position, and thus, should not be construed as limiting the embodiments of the present invention.
In the description herein, the description of the terms "one embodiment," "a preferred embodiment," etc. means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the embodiments of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made to the embodiment by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the embodiments of the present invention should be included in the protection scope of the embodiments of the present invention.
Claims (10)
1. A gas range, comprising:
the gas valve fixing seat (1) is provided with a gas inner cavity (11), a gas inlet (12), a stir-frying gas outlet (13) and an inner and outer ring pipeline gas outlet (14);
a stir-frying pipeline (2);
an inner loop pipeline (3);
an outer loop pipeline (4);
the burner (5) is provided with an air outlet cavity, the gas inlet (12) is communicated with the air outlet cavity sequentially through the gas inner cavity (11), the explosion-stir-frying gas outlet (13) and the explosion-stir-frying pipeline (2), the gas inlet (12) is communicated with the air outlet cavity sequentially through the gas inner cavity (11), the inner and outer ring pipeline air outlets (14) and the inner ring pipeline (3), and the gas inlet (12) is communicated with the air outlet cavity sequentially through the gas inner cavity (11), the inner and outer ring pipeline air outlets (14) and the outer ring pipeline (4);
and the control valve (6) is used for controlling the flow of the fuel gas entering the gas outlet cavity from the stir-frying pipeline (2).
2. Gas range according to claim 1,
the control valve (6) comprises a motor valve and is arranged at the position of the stir-frying gas outlet (13).
3. The gas range of claim 2, wherein the motor valve comprises:
the rotary driving motor (61) is arranged at the mounting opening of the rotary driving motor of the air valve fixing seat (1);
the valve core (62) is arranged in the gas inner cavity (11) and located at the explosion-stir-frying gas outlet (13), the valve core (62) is connected with the rotary driving motor (61), the valve core (62) is provided with a valve core gas inlet cavity (621), the valve core (62) is provided with a plurality of explosion-stir-frying load adjusting channels (622) at intervals along the circumferential direction of the valve core (62), the explosion-stir-frying load adjusting channels (622) are communicated with the valve core gas inlet cavity (621), when the rotary driving motor (61) rotates to drive the valve core (62) to rotate, the explosion-stir-frying load adjusting channels (622) of the valve core (62) are respectively corresponding to the explosion-stir-frying gas outlet (13), and the explosion-stir-frying load adjusting channels (622) are configured to discharge different exhaust quantities to the explosion-stir-frying pipeline (2) through the explosion-stir-frying gas outlet (13).
4. Gas range according to claim 3,
the number of the stir-frying load adjusting channels (622) is five, and the stir-frying load adjusting channels are a first stir-frying load adjusting channel (6221), a second stir-frying load adjusting channel (6222), a third stir-frying load adjusting channel (6223), a fourth stir-frying load adjusting channel (6224) and a fifth stir-frying load adjusting channel (6225) which are arranged in sequence, wherein,
the first stir-frying load adjusting channel (6221) is communicated with the valve core air inlet cavity (621);
the second stir-frying load adjusting channel (6222) is communicated with the valve core air inlet cavity (621);
a first communicating channel (6226) is arranged between the second quick-frying load adjusting channel (6222) and the third quick-frying load adjusting channel (6223), and the third quick-frying load adjusting channel (6223) is communicated with the valve core air inlet cavity (621) through the first communicating channel (6226) and the second quick-frying load adjusting channel (6222) in sequence;
a second communication channel (6227) is arranged between the third burst load adjusting channel (6223) and the fourth burst load adjusting channel (6224), and the fourth burst load adjusting channel (6224) is communicated with the valve core air inlet cavity (621) sequentially through the second communication channel (6227), the third burst load adjusting channel (6223), the first communication channel (6226) and the second burst load adjusting channel (6222);
a third communicating channel (6228) is arranged between the fourth explosion load adjusting channel (6224) and the fifth explosion load adjusting channel (6225), and the fifth explosion load adjusting channel (6225) sequentially passes through the third communicating channel (6228), the fourth explosion load adjusting channel (6224), the second communicating channel (6227), the third explosion load adjusting channel (6223), the first communicating channel (6226) and the second explosion load adjusting channel (6222) to be communicated with the valve core air inlet cavity (621).
5. Gas range according to claim 4,
the inner diameter of the first stir-frying load adjusting channel (6221) is D 1 The inner diameter of the second stir-frying load adjusting channel (6222) is D 2 The first communicating channel (6226) has an inner diameter D 3 The inner diameter of the second communication passage (6227) is D 4 The third communication passage (6228) has an inner diameter D 5 Then there is, D 1 >D 2 >D 3 >D 4 >D 5 。
6. Gas range according to claim 4,
the controller (7) is electrically connected with the rotation driving motor (61) and is used for controlling the rotation driving motor (61) to rotate according to first data of a pot on the furnace end (5); wherein the content of the first and second substances,
the first data is indicative of temperature.
7. Gas burner according to claim 6,
the device also comprises a temperature sensor (8) which is electrically connected with the controller (7) and is used for detecting the first data.
8. Gas range according to claim 1,
the gas outlet cavity comprises an outer ring gas cavity and an inner ring gas cavity, and the gas inner cavity (11) is communicated with the outer ring gas cavity and/or the inner ring gas cavity sequentially through the stir-frying gas outlet (13) and the stir-frying pipeline (2).
9. Gas range according to claim 8,
still include solenoid valve (9) and plug valve (10), solenoid valve (9) set up in gas air inlet (12) department, plug valve (10) set up in interior outer ring pipeline gas outlet (14) department, outer ring pipeline (4) with interior ring pipeline (3) all set up in plug valve (10) and feed through pneumatic valve fixing base (1).
10. Gas range according to claim 9,
the outer ring pipeline (4) is communicated with the outer ring air cavity, and the inner ring pipeline (3) is communicated with the inner ring air cavity of the furnace end (5).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202221769402.4U CN217843971U (en) | 2022-07-07 | 2022-07-07 | Gas kitchen ranges |
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| CN202221769402.4U CN217843971U (en) | 2022-07-07 | 2022-07-07 | Gas kitchen ranges |
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| CN217843971U true CN217843971U (en) | 2022-11-18 |
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| CN202221769402.4U Active CN217843971U (en) | 2022-07-07 | 2022-07-07 | Gas kitchen ranges |
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